Production of the lantibiotic cinnamycin with genes isolated from Streptomyces cinnamoneus

ABSTRACT

A 17 kb nucleic acid fragment, which confers production of the lantibiotic cinnamycin on non-producer Streptomycete strains, has been isolated from  Streptomyces cinnamoneus cinnamoneus  DSM 40005 and characterized. Also provided are variants of the 17 kb fragment including variants in which non-essential genes are deleted and variants in which the propeptide sequence of the cinnamycin structural gene is altered, for example replaced with the propeptide sequence of similar B-type lantibiotics. Also provided are vectors, host cells and methods of lantibiotic production using the nucleic acid of the invention, and libraries of variants.

The present invention relates to materials and methods for the production of the lantibiotic cinnamycin and modified versions thereof.

Lantibiotics are peptides having antibiotic activity, produced by Gram-positive bacteria. They contain, among other modified residues, the thioether amino acids lanthionine and methyllanthionine, which cross-link the peptide chain into a polycyclic structure. They have been classified into two classes, type-A and type-B, though such classification is not unproblematic. Type-A lantibiotics are generally elongate amphiphiles that are capable of forming pores in bacterial and other plasma membranes. Examples are nisin and subtilin. Type-B lantibiotics, by contrast, are globular, conformationally defined peptides that inhibit enzyme functions. Examples are cinnamycin and duramycin.

Activities ascribed to type-B lantibiotics such as cinnamycin include antimicrobial activity (providing potential application as antibiotics), inhibition of angiotensin-converting enzyme (providing a potential application in blood pressure regulation), immunomodulation via inhibition of phospholipase A2 (providing a potential application as anti-inflammatories), and interference with prostaglandin and leucotriene biosynthesis.

Type-B lantibiotics appear to exert their activity by interfering with enzyme activities by blocking the respective substrates. For example, they have been found to inhibit biosynthesis of peptidoglycan; transglycosylation was identified as the target reaction. The substrate for this reaction is the lipid-bound cell wall precursor lipid II. While this is a target for the antibiotic vancomycin, the site of action is different and is a new target binding site not used by any current antibacterial drug.

Antibacterial activity has been observed, in particular with Bacillus strains, with effects described on membrane functions, ATP-dependent proton translocation and Ca²⁺-uptake, and on ATPases. Also, the formation of defined pores in phosphatidylethanolamine-containing planar membranes has been reported. These effects can be attributed to the specific binding of type-B lantibiotics to phosphatidylethanolamine.

Lantibiotics have been shown to have efficacy and utility as food additives and antibacterial agents against Propionibacterium acnes and problematic pathogens, e.g. methicillin-resistant Staphylococcus aureus (MRSA), which has or is developing resistance to many commonly used antibiotics, and Streptococcus pneumoniae.

For reviews, see Sahl and Bierbaum (1998) Annu. Rev. Microbiol. 52:41–79; Jack and Sahl (1995) TIBTECH 13:269–278; Gasson (1995) Chapter 10, Lantibiotics, in Vining and Stuttard (eds) Biotechnology Series: Genetics and Biochemistry of Antibiotic Production, Biotechnological Series 28, pages 283–306.

Accordingly, methods of producing lantibiotics, and the production of variant forms of lantibiotics (which may show improvements over native forms), are highly desirable.

The present inventors have, it is believed for the first time, cloned, sequenced and elucidated structural and regulatory information about the biosynthetic gene cluster for the type-B lantibiotic, cinnamycin, from Streptomyces cinnamoneus cinnamoneus DSM 40005. A plasmid (pDWFT9) comprising a 17 kb DNA segment from this cluster was introduced into a Streptomycete non-producer of cinnamycin (Streptomyces lividans) and conferred the ability to produce cinnamycin. The inventors also propose a minimal set of genes which would be capable of conferring cinnamycin production, and methods for producing variant strains from cinnamycin-producing strains, which variants may produce other novel lantibiotics.

Although the biosynthetic gene cluster for another B-type lantibiotic (mersacidin) has been reported, homology between the mersacidin biosynthetic gene cluster and that reported herein occurs only in one gene (denoted herein as cinM) and is at very low levels.

The 17 kb segment is therefore sufficient to confer upon S. lividans the ability to produce cinnamycin. However, the inventors propose that the segment also comprises genes that are non-essential for this function. Apart from cinA, the cinnamycin structural gene (which has already been described in the literature), none of the other gene sequences necessary for the production of cinnamycin have previously been elucidated. Such genes are proposed herein. Moreover, the predicted gene cinR1 is the key to identifying those genes on pDWFT9 that the inventors propose to be responsible for the normal regulation of cinnamycin production.

The predicted gene cinR1 is a member of a family of transcriptional regulators call the Streptomyces antibiotic regulatory proteins (SARPs). This is the first time the production of a lantibiotic has been reported to be under the control of a SARP (notably the mersacidin gene cluster does not appear to be regulated by a SARP). This family of regulators bind to DNA at specific nucleotide sites. These sites are characterised by repeated conserved motifs of 5 or 6 or 7 bases, repeated at multiples of 11 bases (counting from the first base of each motif). The consensus sequence for the SARP binding sites in the cinnamycin and duramycin biosynthetc clusters is TGAAA (which forms part of an 11 base TGAAANNNNNN repeat unit, where N is any base). The final motif is typically followed by a −10 RNA-polymerase promoter site (the consensus sequence being TAGTGT) at some multiple of 11+5 or 6 bases (e.g. 5, 6, 16, 17, 27, 28, 38 or 39 bases). This has the effect of positioning the conserved motifs on one face of the helix and the −10 promoter site on the opposite side. Inspecting the sequence of FIG. 4 (which shows the 17 kb segment), a single site conforming to this model can be found upstream of an open reading frame designated cinorf7. The site consists of 3 pentamers of TGAAA, separated by 6 bases, followed by the potential −10 promoter sequence TAGTGT.

There are seven co-directional genes downstream of this site, designated cinorf7, cinA, cinM, cinX, CinT, cinH and cinY, that appear to form a single operon. From this, the inventors propose that they are all involved in cinnamycin production or regulation.

The cinA gene has previously been reported as the cinnamycin structural gene (Kaletta et al. (1991) Eur. J. Biochem. 199(2):411–415).

The cinM gene, by homology to known proteins, is thought to encode the protein responsible for post-translationally modifying the translation product of the cinA gene to introduce the lanthionine residues of mature cinnamycin. However, the level of homology with the equivalent gene (mrsM) in the mersacidin biosynthetic gene cluster, which is the only other B-type biosynthetic gene cluster currently known to have been determined, is very weak. The experiments reported herein show cinM to be essential for cinnamycin production.

The cinT and cinH genes are proposed to encode an ABC-cassette transporter, responsible for the export of pre-cinnamycin from the bacterial cell.

The cinX and cinY genes are proposed to be involved in the maturation of pre-cinnamycin (i.e. cleavage of the leader sequence) and/or the introduction of the non-lanthionine modifications of cinnamycin (i.e. a lysino-alanine ring and an hydroxy-aspartate residue). Specifically, cinX is proposed to be responsible for the post-translational modification of the cinnamycin propeptide by the addition of an oxygen atom to the aspartate residue to form beta-hydroxy aspartate. The experiments reported herein indicate that functional deletion of the cinX gene leads to a product having a M_(w) of 2023, compared with 2039 for cinnamycin. Interestingly, this product also shows antibacterial activity, indicating that while cinX may be necessary for cinnamycin production, it may not be essential for the production of variants having one or more activities of lantibiotics.

The cinorf8 predicted gene product is thought to comprise a CoA binding motif, and is thought to be involved in the modification of a cinnamycin intermediate by the attachment/removal of CoA to/from the aspartate residue in the procinnamycin sequence.

The cinorf7 predicted gene product may represent a separate quorum-sensing peptide responsible, in part, for the regulation of cinnamycin production. The experiments reported herein indicate that this gene is not essential for cinnamycin production. In the context of the cinnamycin biosynthetic fragment used herein, however, cinorf7 appears to be essential for high level expression of cinnamycin. This supports its putative regulatory role.

The regulation of the predicted SARP gene (cinR1) is thought to be mediated by the two-component system represented by the predicted genes cinK and cinR which may react to the product of cinorf7.

From this, it is proposed that a cassette comprising fewer genes than the 17 kb segment may also confer cinnamycin production on non-producer strains such as S. lividans.

In particular, it-is proposed that a cassette comprising the cinA, cinM, cinX, cinT, cinH, cinY genes may also confer cinnamycin production on non-producer strains.

However, as indicated above, functional deletion of the cinX gene confers production of a lantibiotic slightly different from cinnamycin. This component of the cassette may therefore be considered optional.

Such a cassette would not, it is proposed, be able to regulate cinnamycin production as in producer strains. A preferred cassette therefore also comprises the SARP binding site and the cinorf7, cinR, cinK and cinR1 genes.

Accordingly, the present invention provides in a first aspect an expression cassette comprising a cinA open reading frame (orf), a cinM orf, optionally a cinX orf, a cinT orf, a cinH orf and a cinY orf.

Such a construct represents the minimal expression cassette which may be predicted by the above model to lead to lantibiotic expression.

Preferably the orfs are provided on a single expression cassette, but it is contemplated that they may be provided separately, for example on two vectors which may be co-introduced into a desired host.

Accordingly in this first aspect, the present invention also provides a set of nucleic acids together comprising a cinA orf, a cinM orf, optionally a cinX orf, a cinT orf, a cinH orf and a cinY orf.

Preferably the set is an isolated set of nucleic acids.

Preferably the cassette or set further comprises a SARP binding site, a cinorf7 orf, a cinR orf, a cinK orf and a cinR1 orf. These are thought to regulate cinnamycin production in producer strains, to provide expression at high cell density. The SARP binding site is preferably upstream of the cinorf7 orf, which preferably forms an operon with the cinA, cinM, cinX, cinT, cinH and cinY orfs.

Preferably the expression cassette or set further comprises one or more of the following orfs, which may also be important for cinnamycin production in producer strains: cinorf3, cinorf4, smallorf, cinz, cinorf8, cinorf9, cinorf10, cinorf11, cinorf12, cinorf13 and cinorf14.

Of these, cinorf3, cinorf13 and cinorf14 in particular are thought not to be essential for cinnamycin (or other lantibiotic) production. cinorf4 and cinorf12 are also thought to be inessential.

Therefore, of the orfs listed above (namely cinorf3, cinorf4, smallorf, cinZ, cinorf8, cinorf9, cinorf10, cinorf11, cinorf12, cinorf13 and cinorf14) one or more (more preferably all) of smallorf, cinZ, cinorf8, cinorf9, cinorf10 and cinorf11 may be included in preferred embodiments of the invention. Of these, preferably cinorf8 and/or cinorfZ are particularly preferred. One or more (preferably all) of cinorf3, cinorf13 and cinorf14 may be absent from, or functionally deleted in, preferred embodiments. Similarly cinorf4 and/or (preferably and) cinorf12 may be absent from, or functionally deleted in, preferred embodiments.

Preferably the cinA orf, for example, has a nucleic acid sequence which encodes a polypeptide having the amino acid sequence which is identical to, or a variant (as further defined below) of, the amino acid sequence of naturally occurring CinA, as set out in FIG. 11.

Preferably the cinA orf has a nucleic acid sequence which is identical to, or a variant (as further defined below) of, the nucleic acid sequence of the cinA orf of the 17 kb segment, as set out in FIG. 4. As indicated in the legend for FIG. 4, the cinA orf runs from base 1671 to base 1907.

The preceding two paragraphs apply mutatis mutandis (and independently) to the other orfs referred to herein. Amino acid sequences for all orfs are given in FIGS. 7 to 27 and the nucleic acid sequence of the 17 kb segment is given in FIG. 4, the legend for which lists the bases at which each orf starts and ends.

In relation to cinA, preferred variants encode CinA variants in which one or more amino acids in the propeptide sequence of CinA is replaced with the amino acid found in the corresponding position in the propeptide sequence of another B-type lantibiotic, especially a similar B-type lantibiotic such as duramycin A, B or C or ancovenin. Combinations of replacements are also contemplated, i.e. one or more amino acids being replaced with the amino acid(s) found in the corresponding positions in the propeptide sequence of one other B-type lantibiotic, and one or more amino acids being replaced with the amino acid(s) found in the corresponding positions in the propeptide sequence of a second or further other B-type lantibiotic.

The propeptide sequence of CinA is shown below, as are the residues in duramycin A, B and C and ancovenin which differ from the propeptide sequence of cinnamycin.

    5     10     15    19     ↓     ↓     ↓    ↓ Cinnamycin: CRQSC SFGPF TFVCD GNTK Duramycin A:  K Duramycin B:     L Duramycin C:  AN  Y  L  WS Ancovenin:  V     L  WS

However, the variants of cinA may (additionally or alternatively) comprise other differences to those corresponding to other known B-type lantibiotics. Again, preferred differences are in the propeptide sequence, preferably in one or more of positions 2, 3, 7, 10, 12 and 13 of the propeptide sequence (i.e. the sites which differ between cinnamycin, duramycin A, B and C and ancovenin).

The expression cassette or set will usually further comprise regulatory sequences suitable for directing transcription and translation in a host cell of the orfs present in the cassette. However, a set of nucleic acids may for example be provided without such regulatory sequences, but may be associated with regulatory sequences for expression in a host cell.

Particularly for embodiments lacking the cinR, cinK, cinR1 and/or cinorf7 orfs and/or the SARP binding site, the regulatory sequences may be heterologous to the 17 kb segment, e.g. constitutive promoters for expression in a host cell. However, in preferred embodiments which include those orfs and the SARP binding site, the regulatory sequences may be identical to or variants of those present in th 17 kb segment. In particular, the cassette or set preferably includes: a regulatory sequence upstream of the cinorf7 orf, which sequence includes the SARP binding site, or a variant thereof; a. regulatory sequence upstream of the cinK orf (when present); and a regulatory sequence upstream of the cinR1 orf (when present). The other orfs may be transcribed by readthrough from these orfs, but may require further regulatory sequences, e.g. comprising ribosome binding sites. These regulatory sequences may correspond to the intergenic sequences of the 17 kb segment (or variants).

A preferred regulatory sequence for the cinorf7 orf may comprise some or all of bases 1199 to 1266 of FIG. 4, or a variant thereof, and especially may comprise bases 1185 to 1228 of FIG. 4, or a variant thereof. The latter sequence comprises the SARP binding site and ribosome binding site present in the 17 kb segment. In an alternative or further definition, the regulatory sequences preferably comprises the consensus sequences identified herein, more preferably in substantially the same relationship to each other and the start of the cinorf7 orf as indicated herein.

A preferred regulatory sequence for the cinK orf may comprise some or all of the complement of bases 13256 to 12823 of FIG. 4, or a variant thereof.

A preferred regulatory sequence for the cinR1 orf may comprise some or all of the complement of bases 15380 to 15161 of FIG. 4, or a variant thereof.

As indicated above, it is also contemplated that other regulatory sequences may be used in conjunction with the nucleic acid sequences identified herein. For example, an expression cassette or set of nucleic acids which lacks the proposed SARP-related regulatory structures identified above (namely the SARP binding site, cinorf7, cinR, cinK and cinR1 genes) might contain genes under the control of a constitutive or inducible promoter. See e.g. Kieser et al (2000) Practical Streptomyces Genetics, The John Innes Foundation for details of such promoters.

Certain of the orfs identified herein appear to be translationally coupled, that is the stop codon of one orf overlaps with the start codon of a co-transcribed orf. It is thought that a ribosome can translate both such orfs stoichiometrically, without requiring a separate ribosome binding site for the second orf.

Preliminary results (not included herein) indicate that a cassette comprising only the cinA, cinM and cinX genes is capable of conferring low levels of cinnamycin production. It is therefore considered that a minimal cassette or set comprising only a cinA orf, a cinM orf and optionally a cinX orf will confer lantibiotic production. Such a cassette or set is also considered to be within this aspect of the invention. Preferred features are as defined above.

In a second aspect, the present invention provides a vector comprising an expression cassette according to the first aspect of the invention. Further it provides a set of vectors comprising a set of nucleic acids according to the first aspect of the invention.

Suitable vectors comprising nucleic acid for introduction into bacteria can be chosen or constructed, containing appropriate additional regulatory elements if necessary, including additional promoters, terminator fragments, enhancer elements, marker genes and other elements as appropriate. Vectors may be plasmids, viral, such as for example a phage or phagemid, as appropriate. For further details see, for example, Sambrook et al (1989) Molecular Cloning, A Laboratory Manual, 2nd ed., Cold Spring Harbor Laboratory Press, Cold Spring Harbor. Many known techniques and protocols for manipulation of nucleic acid, for example in preparation of nucleic acid constructs, mutagenesis, sequencing, introduction of DNA into cells and gene expression, and analysis of proteins, are described in detail in Ausubel et al. (1995) Current Protocols in Molecular Biology, Wiley Interscience Publishers, (1995). Many aspects of the employment of these techniques in the context of Streptomyces spp. are described in detail in Hopwood et al (1985) Genetic manipulation of Streptomyces a laboratory manual (Norwich: John Innes Foundation) and Kieser et al (2000). The disclosures of Sambrook et al, Ausubel et al, Hopwood et al and Kieser et al are all incorporated herein by reference for these and all other purposes

In a third aspect, the present invention provides an expression system comprising an expression cassette or set of nucleic acids according to the first aspect of the invention and an expression system comprising a vector or set of vectors according to the second aspect of the invention.

Preferably the expression system is a host cell or cell culture, although cell-free expression systems are also contemplated. Preferably the host cell or culture is bacterial, more preferably actinomycete, further preferably streptomycete, e.g. S. lividans or S. coelicolor A3(2), especially S. lividans.

The introduction of the expression cassette, set of nucleic acids or vector(s) into a host cell, which may (particularly for in vitro introduction) be generally referred to without limitation as transformation, may employ any available technique. For bacterial cells, suitable techniques may include calcium chloride transformation, polyethyleneglycol assisted transformation, electroporation, conjugation and transfection or transduction using bacteriophages.

In a fourth aspect, the present invention provides a method of expressing nucleic acid of interest, the method comprising providing a host cell (or other expression system) according to the third aspect and culturing the host cell, so as to express the nucleic acid of interest.

For the avoidance of doubt, the nucleic acid of interest will be the expression cassette or set of nucleic acids of the first aspect, such that culturing the host cell will lead to the production of cinnamycin, or a variant thereof (for example deoxycinnamycin, in which the aspartate residue has not been post-translationally converted by the CinX gene product into beta-hydroxy aspartate, or the products of the expression of variant forms of cinA, with or without cinX).

Preferably the nucleic acid of interest is expressed substantially only when the host cell culture reaches high cell density, more preferably at or close to the stationary phase of host cell culture. Cell cultures at or close to stationary phase may have OD₆₅₀ values in the range of 1–20.

Known methods of culturing cells are well known in the art, for example from Sambrook et al (1989), Ausubel et al (1992), and (in particular for Streptomyces spp.) Hopwood et al (1985) and Kieser et al (2000).

The expression products of the expression systems may be collected and purified. This may be achieved by conventional methods. See for example McDaniel et al. (1993).

In a fifth aspect, therefore, the present invention provides an expression product produced according to the method of the fourth aspect of the invention.

In a sixth aspect, the present invention provides a nucleic acid molecule consisting essentially of one or more of the following orfs: cinorf3, cinorf4, smallorf, cinorf7, cinA, cinM, cinX, cinT, cinH, cinY, cinZ, cinorf8, cinorf9, cinR, cinK, cinorf10, cinorf11, cinR1, cinorf12, cinorf13 and cinorf14, optionally with a regulatory region or regulatory regions. Where present, the regulatory region(s) may comprise promoter sequence(s) for the orf(s). Where two or more orfs are present, a regulatory region for one or more of those orfs may be provided between orfs.

The orfs may be as previously defined.

In relation to cinorf3 and cinorf14, which are disclosed herein in incomplete form, the skilled person will be readily able to obtain the full length orf using known techniques.

In a seventh aspect, the present invention provides the use of one or more nucleic acid molecules as defined in the sixth aspect, in or for the production of a lantibiotic in an expression system.

In an eighth aspect, the present invention provides a polypeptide encodable by one of the following orfs: cinorf3, cinorf4, smallorf, cinorf7, cinA, cinM, cinX, cinT, cinH, cinY, cinZ, cinorf8, cinorf9, cinR, cinK, cinorf10, cinorf11, cinR1, cinorf12, cinorf13 and cinorf14. Preferably the polypeptide is substantially isolated from other proteins with which it is naturally associated.

The polypeptide preferably has an amino acid sequence as shown in one of FIGS. 7 to 27. However, this aspect also provides polypeptides which are variants of those amino acid sequences.

In a ninth aspect, the present invention provides a vector including a nucleic acid according to the sixth aspect. In embodiments in which the nucleic acid lacks a promoter or promoters for the orf(s) it contains, the vector preferably includes a promoter in operative association with the orf(s).

In a tenth aspect, the present invention provides an expression system containing one or more nucleic acids according to the sixth aspect and an expression system containing a vector according to the ninth aspect.

Preferably the expression system is a cell. Any appropriate cell may be used (e.g. a standard E. coli overexpression system). See for example Sambrook et al (1989) and Ausubel et al (1992). However, bacterial, actinomycete and streptomycete cells are preferred as previously indicated.

In an eleventh aspect, the present invention provides a method of producing a polypeptide according to the eighth aspect, the method comprising producing the polypeptide in an expression system according to the tenth aspect.

The polypeptide may be purified from the expression system by conventional methods.

As has been demonstrated previously (Sahl and Bierbaum 1998), the proteins which are involved in post-translational processing and modification of lantibiotics (e.g. to introduce lanthionine and/or methyllanthionine residues) may be used in vitro to modify other proteins (especially other lantibiotics). See for example the reviews cited in the introduction and references cited therein. It is proposed that such use may be made of one or more of the polypeptides above, especially CinM, CinX and/or CinY. Indeed, in the experiments described herein, the cinA gene on the pDWFT9 plasmid was modified to encode a polypeptide having the propeptide sequence of duramycin A or B instead of cinnamycin structural gene. This still led to an antibacterially active product, indicating that post-translational modification was occurring despite the change in propeptide sequence.

The inventors also propose that the materials and methods of the present invention be modified, e.g. to produce variant forms of cinnamycin and/or to affect the production of cinnamycin or variants. In particular, it is contemplated that the mutation of one or more orfs or regulatory sequences of the 17 kb segment may lead to changes of this sort. For example, non-silent mutations in the cinA orf will produce changes in the amino acid sequence encoded by the orf, which changes may lead to a variant form of cinnamycin having one or more different properties compared to naturally occurring cinnamycin. Such modification has been demonstrated herein and is particularly preferred. Similarly, mutations of the orfs encoding proteins thought to be responsible for the post-translational modification of the primary transcript of cinA may lead to different post-translational modifications. Mutation of the regulatory sequences may lead to differences in the control of cinnamycin (or variant) production. Such modified materials and methods are also included within the scope of the preceding aspects.

Mutagenesis may be performed using available methods e.g. chemical mutagenesis, alanine-scanning mutagenesis, site-directed mutagenesis using oligonucleotides, error-prone PCR or by propagating target nucleic acid in an appropriate plasmid in a mutator strain, e.g. the XL1-Red strain of E. coli (Stratagene). The protocol for this procedure is described in Greener and Callahan (1993) Strategies 6, 32–34. Mutagenesis may be carried out on a particular orf or group of orfs (or regulatory seqence(s)), which is then cloned back into a nucleic acid containing unmutated sequence, or the entire nucleic acid of interest (e.g. the 17 kb segment) may be subjected to mutagenesis.

In particular, the methods and materials of the present invention, relating to the cinnamycin biosynthetic cluster, may be used in conjunction with material derived from other lantibiotic-producing strains, e.g. to expose primary translation products of other lantibiotics (such as other B-type lantibiotics, e.g. duramycin) to the post-translational modification enzymes of the present invention or vice versa. This could be done in vitro, using the translation products, or in vivo, e.g. by introducing the structural gene for another lantibiotic into a host cell having other genes of the cinnamycin biosynthetic pathway.

In a further aspect, the present invention provides a method for producing a library of lantibiotic-producing host cells, the method comprising:

providing a plurality of host cells respectively transformed with different nucleic acids, sets of nucleic acids, vectors or sets of vectors as defined in the first or second aspects.

Preferably at least some of the nucleic acids, sets of nucleic acids, vectors or sets of vectors differ in the propeptide-encoding region of cinA. However, other mutations are contemplated.

In this aspect, there is also provided such a library of lantibiotic-producing host cells, preferably produced or producible according to the method of this aspect.

Such a library may be screened for desirable properties. Preferably it is initially screened for lantibiotic production (e.g. by determining the effect on B. subtilis growth), and then screened for interesting and/or advantageous mutations. The library may be limited, e.g. following such an initial screening step, to host cells which display lantibiotic production.

In a further aspect, the invention provides a method of producing a library of lantibiotics, the method comprising:

-   -   providing a library of lantibiotic-producing host cells         according to the previous aspect; and     -   culturing said host cells under conditions suitable for         lantibiotic production.

The method may include one or more steps of purifying the lantibiotics thus produced.

This aspect also provides such a library of lantibiotics, preferably produced or producible according to the method of this aspect.

Another aspect of the invention pertains to a composition comprising a lantibiotic produced or producible as provided above and a pharmaceutically acceptable carrier or diluent.

Another aspect of the invention pertains to a lantibiotic produced or producible as provided above for use in a method of treatment of the human or animal body.

Another aspect of the invention pertains to a method of treatment, in vitro or in vivo, comprising contacting a cell with an effective amount of a lantibiotic produced or producible as provided above.

References herein to orfs, genes, coding regions and nucleic acids are not to be interpreted as being restricted to oafs, genes, coding regions and nucleic acids having the specific nucleic acid sequences disclosed herein. Rather, genes, coding regions and nucleic acids having variants of those sequences are also included. Genes, coding regions and nucleic acids having such specific sequences are preferred embodiments. Thus, for example, a reference to a cinA orf is not to be interpreted as being restricted to an orf having the sequence from residue 1671 to 1907 of FIG. 4 but also includes variants.

Similarly, references herein to polypeptides are not to be interpreted as being restricted to polypeptides having the specific amino acid sequences disclosed herein. Rather, polypeptides having variants of those sequences are also included. Polypeptides having such specific sequences are preferred embodiments. Thus, for example, a reference to a CinA polypeptide is not to be interpreted as being restricted to a polypeptide having the amino acid sequence shown in FIG. 11, but also includes variants.

References herein to promoters are not to be interpreted as being restricted to nucleic acids having the sequence of all or part of a specific intergenic region disclosed herein. Again, promoters having variants of those intergenic sequences are also included and the specific intergenic sequences (or parts thereof) are preferred embodiments.

In all cases, where a preferred embodiment of an orf, gene, nucleic acid, polypeptide or promoter is defined by reference to a specific sequence, the invention in its broader sense is intended to include embodiments having variants of that specific sequence. Nevertheless, the specific sequences disclosed herein represent preferred embodiments.

The term variant as used herein in relation to a particular nucleic acid (the reference nucleic acid) denotes: any nucleid acid having a sequence which is different from that of the reference nucleic acid, but which is its complement or which shows significant nucleic acid sequence identity with, or hybridisation under stringent conditions to, the reference nucleic acid or its complement or a fragment of the reference nucleic acid or its complement; or any nucleic acid which encodes an amino acid sequence having significant amino acid sequence identity with the amino acid sequence encoded by the reference nucleic acid, or a fragment of that nucleic acid. The term variant also refers to nucleic acids which differ from each other due only to the degeneracy of the genetic code, and which therefore encode identical deduced amino acid sequences.

The term variant as used herein in relation to a particular polypeptide (the reference polypeptide) denotes: any polypeptide having an amino acid sequence which is different from, but which shows significant amino acid sequence identity with, the amino acid sequence of the reference polypeptide, or a fragment of that polypeptide.

Variant nucleic acids of the invention are further defined as follows. If a variant nucleic acid of the invention is introduced into the 17 kb nucleic acid fragment identified herein in place of the sequence of which it is a variant, and the recombinant fragment is introduced into a suitable host cell under suitable conditions for lantibiotic production (e.g. as shown in the Examples), then production of a molecule having one or more activities of a lantibiotic (especially antibiotic activity) will result. Preferably production will be regulated to occur at high cell density.

Unless otherwise specified, significant amino acid sequence identity is preferably at least 80%, more preferably 85%, 90% or 95%, still more preferably 98% or 99% and/or significant nucleic acid sequence identity is preferably at least 50%, more preferably 60%, 70%, 80% or 90%, still more preferably 95%, 98% or 99%.

Significant amino acid sequence identity is preferably shown between the variant polypeptide (or a portion thereof) and a fragment of at least 10 amino acids of the reference polypeptide, more preferably a fragment of a least 20, 30 or 40 amino acids, still more preferably a fragment of 60, 80 or 100 amino acids, more preferably the entire reference polypeptide.

Significant nucleic acid sequence identity is preferably shown between the variant nucleic acid (or a portion thereof) and a fragment of at least 30 residues of the reference nucleic acid, more preferably a fragment of a least 60, 90 or 120 residues, still more preferably a fragment of 180, 240 or 300 residues, more preferably the entire reference nucleic acid.

A percent (%) amino acid sequence identity” is defined as the percentage of amino acid residues in a candidate sequence that are identical with the amino acid residues in the sequence with which it is being compared, after aligning the sequences and introducing gaps, if necessary, to achieve the maximum percent sequence identity, and not considering any conservative substitutions as part of the sequence identity. The % identity values used herein are generated by WU-BLAST-2 which was obtained from Altschul et al. (1995); blast.wustl/edu/blast/README.html. WU-BLAST-2 uses several search parameters, most of which are set to the default values. The adjustable parameters are set with the following values: overlap span=1, overlap fraction=0.125, word threshold (T)=11. The HSPS and HSPS2 parameters are dynamic values and are established by the program itself depending upon the composition of the particular sequence and composition of the particular database against which the sequence of interest is being searched; however, the values may be adjusted to increase sensitivity. A % amino acid sequence identity value is determined by the number of matching identical residues divided by the total number of residues of the ‘longer” sequence in the aligned region, multiplied by 100. The “longer” sequence is the one having the most actual residues in the aligned region (gaps introduced by WU-BLAST-2 to maximize the alignment score are ignored.

“Percent (%) nucleic acid sequence identity” is defined as the percentage of nucleotide residues in a candidate sequence that are identical with the nucleotide residues in the sequence under comparison. The identity values used herein were generated by the BLASTN module of WU BLAST-2 set to the default parameters, with overlap span and overlap fraction set to 1 and 0.125, respectively.

In relation to variants of the promoters used in the present invention, nucleic acid sequence identity is preferably assessed over a sequence of at least 30 residues, more preferably 40 or 50 residues, still more preferably 60 residues.

“Stringent conditions” or “high stringency conditions”, as defined herein, may be identified by those that: (1) employ low ionic strength and high temperature for washing, for example 0.015 M sodium chloride/0.0015 M sodium citrate/0.1% sodium dodecyl sulfate at 50° C.; (2) employ during hybridization a denaturing agent, such as formamide, for example, 50% (v/v) formamide with 0.1% bovine serum albumin/0.1% Ficoll/0.1% polyvinylpyrrolidone/50 mM sodium phosphate buffer at pH 6.5 with 750 sodium chloride, 75 mM sodium citrate at 42° C.; or (3) employ 50% formamide, 5×SSC (0.75 m NaCl, 0.075 M sodium citrate), 50 mM sodium phosphate (pH 6.8), 0.1% sodium pyrophosphate, 5× Denhardt's solution, sonicated salmon sperm DNA (50 μg/ml), 0.1 SDS, and 10% dextran sulfate at 42° C. in 0.2×SSC (sodium chloride/sodium citrate) and 50% formamide at 55° C., followed by a high-stringency wash consisting of 0.1×SSC containing EDTA at 55° C.

When a nucleic acid of interest is an operative association with a promoter or regulatory sequence, the promoter/regulatory sequence is able to direct transcription of the nucleic acid of interest in an appropriate expression system, with, the nucleic acid of interest in the correct reading frame for translation. Preferably when a nucleic acid of interest is in operative association with a promoter/regulatory sequence, the transcript of the nucleic acid of interest contains an appropriately located ribosome binding site for expression in an appropriate expression system of the polypeptide encoded by the nucleic acid of interest. See for example Sambrook et al. (1989) and Ausubel et al. (1995).

When a nucleic acid is referred to as “isolated”, this may mean substantially or completely isolated from some or all other nucleic acid normally present in Streptomyces cinnamoneus cinnamoneus DSM40005, especially nucleic acid from outside the 17 kb segment identified herein. However, the use of for example a Streptomyces cinnamoneus cinnamoneus DSM40005 regulatory sequence with an otherwise isolated nucleic acid is not to be regarded as prevented such nucleic acid from being deemed “isolated”. When a polypeptide is referred to as “isolated”, this may mean substantially or completely isolated from some or all polypeptides normally expressed by Streptomyces cinnamoneus cinnamoneus DSM40005, especially polypeptides encoded by nucleic acid from outside the 17 kb segment identified herein.

Formulations

The lantibiotics of the present invention may be formulated together with one or more other pharmaceutically acceptable ingredients well known to those skilled in the art, including, but not limited to, pharmaceutically acceptable carriers, adjuvants, excipients, diluents, fillers, buffers, preservatives, anti-oxidants, lubricants, stabilisers, solubilisers, surfactants (e.g.; wetting agents), masking agents, colouring agents, flavouring agents, and sweetening agents. The formulation may further comprise other active agents, for example, other therapeutic or prophylactic agents.

Thus, the present invention further provides pharmaceutical compositions, as defined above, and methods of making a pharmaceutical composition comprising admixing at least one active compound, as defined above, together with one or more other pharmaceutically acceptable ingredients well known to those skilled in the art, e.g., carriers, adjuvants, excipients, etc. If formulated as discrete units (e.g., tablets, etc.), each unit contains a predetermined amount (dosage) of the active compound.

The term “pharmaceutically acceptable” as used herein. pertains to compounds, ingredients, materials, compositions, dosage forms, etc., which are, within the scope of sound medical judgement, suitable for use in contact with the tissues of the subject in question (e.g., human) without excessive toxicity, irritation, allergic response, or other problem or complication, commensurate with a reasonable benefit/risk ratio. Each carrier, adjuvant, excipient, etc. must also be “acceptable” in the sense of being compatible with the other ingredients of the formulation.

Suitable carriers, adjuvants, excipients, etc. can be found in standard pharmaceutical texts, for example, Remington's Pharmaceutical Sciences, 18th edition, Mack Publishing Company, Easton, Pa., 1990; and Handbook of Pharmaceutical Excipients, 2nd edition, 1994.

The experimental basis of the present invention will now be described in detail, by way of example only, with reference to the accompanying drawings, in which:

FIG. 1 shows the DNA sequence of probe CK. In this figure and elsewhere, the base N may represent A, C, G or T (or U for RNA).

FIG. 2 shows the DNA sequence of pDWCC1. The primers BB3 and BB4 are marked in bold and labelled.

FIG. 3 shows the DNA sequence of probe BB.

FIG. 4 shows the sequence of the cinnamycin cluster from Streptomyces cinnamoneus cinnamoneus 40005 as present on the plasmid pDWFT9. The probable SARP binding site is indicated in bold and the probable −10 promoter site is indicated in bold italics. Open reading frames in the sequence are as follows (the numbers represent the first and last base pairs): cinorf3=complement (346 . . . 1) (NB as this is an incomplete orf, the end of the sequence is not a stop codon); cinorf4=454. . . 1026; smallorf=1109 . . . 1198; cinorf7=1267 . . . 1626; cinA=1671 . . . 1907; cinM=2059 . . . 5325; cinX=5340 . . . 6317; cinT=6543 . . . 7472; cinH=7469 . . . 8341; cinY=8444 . . . 9466; cinZ=complement (10171 . . . 9545); cinorf8=10246 . . . 10665; cinorf9=10758 . . . 11078; cinR=complement (11761 . . . 11111); cinK=complement (12822 . . . 11758); cinorf10=13257 . . . 13754; cinorf11=13754 . . . 14944; cinR1=complement (15160 . . . 14375); cinorf12=15381 . . . 15872; cinorf13=15912 . . . 16496; cinorf14=16549 . . . 17083 (NB as this is an incomplete orf, the end of the sequence is not a stop codon).

FIG. 5 shows the order and orientation of the putative genes of the cinnamycin cluster of Streptomyces cinnamoneus cinnamoneus 40005 and also represents all of the Streptomyces cinnamoneus cinnamoneus 40005 DNA inserted into pOJ436 to give pDWFT9. The putative genes represented in this diagram as capital letters are prefixed in the text as cin whilst those with numbers are prefixed as cinorf. Restriction sites cut by enzymes used in the cloning process are marked along with the first base-pair position of the relevent recognition site in the sequence given in FIG. 4. This is a schematic diagram and not to scale.

FIG. 6 shows the DNA sequence of probe 1.1.

FIG. 7 shows the deduced amino acid sequence encoded by cinorf3. This is an incomplete orf. The MW is shown.

FIGS. 8 to 26 respectively show the deduced amino acid sequences encoded by each of the orfs from cinorf4 on the left hand side of FIG. 5 to cinorf13 on the right hand side of FIG. 5. The MWs are listed.

FIG. 27 shows the deduced amino acid sequence encoded by cinorf14. This is an incomplete orf. The MW is listed.

FIG. 28 shows the DNA sequence of pCK51.

FIG. 29 shows the DNA sequence of the tetracycline resistance cassette of pDWFT33.

EXAMPLE 1 The Cloning of the Cinnamycin Cluster of Streptomyces Cinnamoneus Cinnamoneus DSM 40005

Materials

Plasmid pCK51 (Kaletta C et al (1991) Eur. J. Biochem 199(2): 411–415) carrying the structural gene for cinnamycin (cinA) along with sequence data for this plasmid was obtained from Dr Torsten Helge Stein of the Institut für Mikrobiologie, der Johann Wolgang Goethe-Universität Frankfurt, Biozentrum Niederursel, Marie-Curie-Straβe 9, D-60439 Frankfurt/Main, Germany.

Streptomyces cinnamoneus cinnamoneus strains DSM 40646 and DSM 40005 (duramycin and cinnamycin producers respectively) were obtained from the German Collection of Microorgansims, DSM.

Streptomyces lividans 1326 and Escherichia coli DH5α are common laboratory strains.

Methods

Cloning of the genes for Cinnamycin Production

An approximately 2.8 kb NdeI (see FIG. 28 cut site 2033CA↓TATG)/BamHI (see FIG. 28 cut site 4844G↓GATCC) restriction fragment was isolated from pCK51 by agarose gel electrophoresis using the Qiagen gel extraction kit. This restriction fragment lies downstream of cinA and carries the 5′ part of a putative lanM type gene that encodes a protein thought to be involved in the production of lanthionine residues. The restriction fragment was then used to produce a radio-labelled probe (Pharmacia Oligolabelling Kit), probe-CK (see FIG. 1), for use in Southern analysis and colony hybridisations.

Genomic DNA was isolated from Streptomyces cinnamoneus cinnamoneus 40646 and cut with a series of restriction endonucleases (Asp7l8, BamHI, BglII, SacI, SalI, XhoI, and PstI) before being subject to Southern analysis using probe-CK. An approximately 5 kb BglII restriction fragment was obtained that was selected for cloning. Genomic DNA digested with BglII and fragments of about 5 kb in size were isolated by agarose gel electrophoresis and ligated into BamHI cut pBluescriptII KS (Stratagene). The resulting ligation mixture was transformed into E. coli DH5α to form a mini-library of BglII fragments of about 5 kb. A clone, pDWCC1 (see FIG. 2), carrying the BglII fragment detected by Southern analysis was isolated from this library by colony hybridisation using probe-CK. Sequencing of pDWCC1 revealed the isolated BglII fragment to be 4943 bp long with one end encoding the 3′ end of a lanM type gene corresponding to probe-CK.

Sequence information from pDWCC1 was used to design a probe to the lanM type gene and used in the screening of Streptomyces cinnamoneus cinnamoneus DSM 40005 genomic DNA. A DNA fragment was prepared by polymerase chain reaction (PCR) using Taq polymerase. The primers used were BB3 (=5′-GCC TAC GAG GAC CGG TAC GTC G-3′, in bold in FIG. 2 start 1050 stop 1071) and BB4 (=5′-GGC GAA GCG CAG GAA GAG CTC G-3′, complement in bold in FIG. 2 start 1343 stop 1322) and a fragment of 294 bp in length was produced. This PCR fragment was used to produce a radiolabelled probe, probe-BB (see FIG. 3) and used in Southern analysis and colony hybridisation.

Genomic DNA was isolated from Streptomyces cinnamoneus cinnamoneus DSM 40005 and cut with a series of restriction endonucleases (BamHI, BglII, SacI, SalI, Xhol, and PstI) before being subject to Southern analysis using probe-BB. An approximately 5 kb BglII restriction fragment was obtained that was selected for cloning. Genomic DNA was digested with BglII and fragments of about 5 kb were isolated by agarose gel electrophoresis and ligated into BamHI cut pBluescriptII KS (Stratagene). The ligation mixture was transformed into E. coli DH5α to form a mini-library of BglII fragments of about 5 kb. Two clones, pDWFT1 and pDWFT2 (the sequences of which correspond to that starting at position 3756 and stopping at position 8734 of FIG. 4) carrying the BglII fragment detected by Southern analysis were isolated from this library by colony hybridisation using probe-BB. These two plasmids were subsequently shown to contain identical inserts in opposite orientations by sequencing with pBluescriptII KS reverse primer (Stratagene). Sequencing of pDWFT1 revealed the isolated BglII fragment to be 4979 bp long (see FIG. 4 and 5) with one end encoding the 3′ part of a lanM type gene corresponding to probe-BB. Computer analysis of the sequence data for pDWCC1 and pDWFT1 revealed the two BglII fragments to be 88.8% identical along the entire lengths of both fragments. Subsequently an approximately 5 kb BamHI fragment, which was also detected by Southern analysis using probe-BB, was cloned in a similar procedure to give pDWFT4 (the sequence of which corresponds to that starting at position 1 and stopping at position 4872 of FIG. 4).

Sequencing of pDWFT4 revealed the BamHI fragment to be 4872 bp in length (see FIGS. 4 and 5) and carries the 5′ end of the lanM type gene and cinA. Comparison of the sequence data for the BamHI fragments of pDWFT4 and the sequence data provided for pCK51 showed the two fragments to be 97.3% identical along the entire lengths of both fragments.

A PstI fragment of approximately 1.1 Kb from the end of the BglII fragment of pDWFT2 distal to the end carrying the lanM type gene was isolated by agarose gel electrophoresis (This corresponds to the region starting at position 7612 and stopping at position 8734 of the sequence shown in FIG. 4 plus a short length of the pBluescriptII KS poly-linker (see FIG. 6)). This fragment was then used to prepare a radiolabelled probe, probe-1.1 (see FIG. 6) for use in Southern analysis and colony hybridisations. Using probe-1.1 an approximately 11 kb Asp718 fragment from Streptomyces cinnamoneus cinnamoneus DSM 40005 genomic DNA was obtained by Southern analysis. This fragment was then isolated and cloned using probe-1.1 in a procedure similar to that described for pDWCC1 to give pDWFT5 (The sequence of which corresponds to the region starting at position 5423 and stopping at position 17083). Sequencing of this plasmid revealed it to be 11661 bp in length with a 3312 bp overlap with pDWFT1 (see FIGS. 4 and 5 ).

The cloned fragments from pDWFT1, pDWFT4 and pDWFT5 were then cloned together to give a single piece of DNA, pDWFT9 (see FIGS. 4 and 5), with the various parts in the same order and orientations as in the Streptomyces cinnamoneus cinnamoneus DSM 40005 chromosome. Analysis of the sequence data (using the Wisconsin GCG package Version 10.1-Unix: gap creation penalty 50; gap extension penalty 3) for these three plasmids shows that they cover a single 17083 bp region of the Streptomyces cinnamoneus cinnamoneus DSM 40005 genome. The sequence data revealed that there were only two Asp718 sites (GGTACC) within this region. One of these sites is within the region covered by pDWFT1 and corresponds to one end of the Asp718 fragment of pDWFT5 whilst the other is at the other end of the region covered by pDWFT5. The region of pDWFT1 not overlapped by either pDWFT4 or pDWFT5 corresponds to a single 562 bp long BamHI/Asp718 fragment. The BamHI fragment of pDWFT4 was ligated together with the 562 bp BamHI/Asp718 fragment of pDWFT1 to restore one end of the cluster to the wild type conformation. Subsequently the Asp718 fragment of pDWFT5 was ligated to this to restore the whole cluster to the wild type conformation.

The first step in this process was to clone the 562 bp BamHI (see FIG. 4 cut site 4867G↓GATCC)/Asp718 (see FIG. 4 cut site 5423G↓GTACC) fragment from pDWFT1 into pBluescriptII KS cut with BamHI/Asp718 to give pDWFT6. The cloned 5 kb BamHI fragment from pDWFT4 (see FIG. 4 cut sites 1G↓GATCC and 4867G↓GATCC) was then cloned into BamHI cut pDWFT6 to give pDWFT7. The orientation of the fragments in pDWFT7 was checked by restriction analysis using standard procedures (Sambrooke J et al (1989) Molecular Cloning; A Laboratory Manual, Cold Spring Harbor Laboratory Press Chapter 1 and Chapter 6) to ensure that it conformed to the native conformation. This BamHI/BamHI/Asp718 fragment was then cut from pDWFT7 on a single Asp718/XbaI fragment (the sequence of which corresponds to the region starting at position 1 and stopping at position 5428 plus a short region of pBluescriptII KS poly-linker) and cloned into pQJ436 (Bierman M et al (1992) Gene 116, pp 43–49) to give pDWFT8. The Asp718 fragment from pDWFT5 (see FIG. 4 cut sites 5423G↓GTACC and 17078G↓GTACC) was cloned into pDWFT8 cut with Asp718 to give pDWFT9. The orientation of the fragments was checked by restriction analysis with BglII to ensure that the fragment corresponding to the BglII fragment of pDWFT1 had been restored. This plasmid pDWFT9 is composed of 17083 bp of DNA corresponding exactly to the sequence of the Streptomyces cinnamoneus cinnamoneus DSM 40005 chromosome, plus a small region of pBluescriptII KS poly-linker, cloned into pOJ436.

Streptomyces lividans 1326 was then transformed with pDWFT9 and also the basic vector pOJ436 to produce test and control strains, respectively. Those strains possessing pDWFT9 were labelled S. lividans DW9a-1-8 and those possessing pOJ436 were labelled S. lividans DW436-1-4.

Bioassays for Cinnamycin Production

The strains tested, DW9a1-8 and DW436-1-4, were grown for 5–7 days on R2YE medium (Practical Streptomyces Genetics (2000) Kieser T. et al The John Innes Foundation p. 408). An over-night culture of B. subtilis was used to inoculate a 10 ml LB media culture which was grown until its OD=0.3–0.4 (600 nm) (between 5–8 hours). A 0.5 ml aliquot of this culture was then used to inoculate 5 ml of soft Oxoid nutrient agar at 55° C. which was mixed by inversion and then poured immediately over the plate to be assayed. The plate was tilted until an even covering of the B. subtilis overlay was achieved. The assay plate was then grown at 37° C. over-night after which it was checked for inhibition of the growth of B. subtilis.

Detection of Cinnamycin by Mass Spectrometry

Streptomyces lividans strains were grown for 5–7 days in either YEME or TSB medium (Practical Streptomyces supra) after which the cells were removed by centrifugation. The supernatant was then extracted twice with an equal volume of ethyl acetate with the aqueous fraction being retained both times. The aqueous fraction was extracted twice with butanol equilibrated with water, with the butanol fraction being retained and both fractions being pooled. The butanol was then extracted with either 10× or 2× volumes of 10% formic acid which was subsequently used for analysis on a MALDI-TOF mass spectrometer.

Results

Bioassays for Cinnamycin Production

The results in Table 1 show that S. cinnamoneus cinnamoneus DSM 40005 inhibits the growth of B. subtilis and that strains of S. lividans which carry the vector pOJ436 upon which pDWFT9 is based, but which do not carry the putative cinnamycin cluster, do not show any inhibition of the growth of B. subtilis. Strains of S. lividans carrying the plasmid pDWFT9, which encodes the putative cinnamycin cluster from S. cinnamoneus cinnamoneus DSM 40005 inhibit the growth of B. subtilis. Since S. cinnamoneus cinnamoneus DSM 40005 inhibits the growth of B. subtilis and a known activity of cinnamycin is the inhibition of the growth of the B. subtilis strains this result provides evidence that the S. lividans strains carrying the putative cinnamycin cluster, carried on pDWFT9, are producing cinnamycin.

Detection of Cinnamycin by Mass Spectrometry

The results in Table 2 show that molecules with molecular weights similar to cinnamycin (2039.4 as calculated from propeptide sequence data and structural data) were present in the supernatants of liquid cultures of Streptomyces cinnamoneus cinnamoneus DSM 40005 and S. lividans DW9a-1, the strain carrying the carrying the putative cinnamycin cluster on plasmid pDWFT9. No molecules with this molecular weight were detected in supernatants of liquid cultures of S. lividans DW436-4 which carries pOJ436, the vector upon which pDWFT9 is based but without the cinnamycin cluster. This is taken as evidence that S. lividans DW9a-1 which carries the putative cinnamycin cluster is producing cinnamycin.

Analysis of the Sequence of the Cinnamycin Cluster of Streptomyces cinnamoneus cinnamoneus DSM 40005

The plasmid pDWFT9 possesses the Streptomyces cinnamoneus cinnamoneus DSM 40005 cinnamycin cluster genes that are vital for the expression of cinnamycin in S. lividans. The sequence data for this plasmid is represented in FIG. 4 which, together with its legend, also lists the putative genes, and the positions of these genes, along with other vital features encoded within this sequence. The positions of these genes were determined by using the frameplot program (accepting the default values) and, when there was more than one available start codon, looking for a potential ribosome binding site (Shine Dalgarno sequence) taking the sequence GGAGG as the ideal (Practical Streptomyces Genetics (2000) Kieser T. et al The John Innes Foundation p. 386). The order and relative orientation of the putative genes is shown in the diagram FIG. 5. The frameplot program is publicly available on the web at http://watson.nih.go.jp/˜jun/cgi-bin/frameplot.pl (Ishikawa, J. and Hotta, K. FEMS Microbiol. Lett. 174:251–253 (1999)). There are 21 potential genes in this sequence which potentially represent real genes and are discussed individually below starting at the beginning of the sequence and going through in the order that they occur. The database search program Blast P, based at the NCBI, was used to look for similarities between the protein translations of the potential genes given here and those in the publicly available database using the version of Blast available at the provided web page.

cinorf3 (FIG. 7). Incomplete predicted gene with the 3′ end being truncated.

cinorf4 (FIG. 8) The protein translation product of this predicted gene has no homology with any gene product of known function.

smallorf (FIG. 9) This motif starts at residue 1109 and ends at residue 1198 of FIG. 1.

cinorf7 (FIG. 10) The protein translation product of this predicted gene has no homology to any gene product of known function.

cinA (FIG. 11) This is the cinnamycin structural gene. The protein translation product has 100% identity with the gene product of the published cinA gene (Kaletta C et al (1991) Eur. J. Biochem 199(2): 411–415).

cinM (FIG. 12) The protein translation product of this predicted gene is thought to be a modifying enzyme.

cinX (FIG. 13) The protein translation product of this predicted gene has no homology to any gene product of known function.

cinT (FIG. 14) The protein translation product of this predicted gene appears to be translationally coupled to the translation product of the predicted cinH gene.

cinH (FIG. 15) The protein translation product of this predicted gene appears to be translationally coupled to the translation product of the predicted cinT gene.

cinY (FIG. 16) The protein translation product of this predicted gene has no homology to any gene product of known function.

cinZ (FIG. 17) The protein translation product of this predicted gene has 40% homology over its entire length with the C-terminal third of the PepQ protein from E. coli (embl locus ECPEPQ, accession X54687.1).

cinorf8 (FIG. 18) The protein translation product of this predicted gene has greater than 47% identity over its full length with a protein from E. coli (pir: locus D64837).

cinorf9 (FIG. 19) The protein translation product of this predicted gene has no homology to any gene product of known function.

cinR (FIG. 20) The protein translation product of this predicted gene has homology over its full length with many putative response regulators from Streptomyces coelicolor A3(2). For example, a hit using Blast P (available from the NCBI website at www.ncbi.nlm.nih.gov; word size: 3; matrix: blosum 62; gap costs: existence: 11, extension: 1) recorded 48% identity over the entire length of the putative CinR protein. This correlates with the AbsA2-protein which is thought to be involved in global negative regulation of Streptomyces coelicolor antibiotic synthesis (Brian, P., Riggle, P. J., Santos, R. A. and Champness, W. C. J. Bacteriol. 178 (11), 3221–3231 (1996)). This predicted gene appears to be translationally coupled to the predicted cinK gene.

cinK (FIG. 21) The protein translation product of this predicted gene has homology over its entire length with many putative histidine kinases from Streptomyces coelicolor A3 (2). For example, a hit using Blast P (default parameters) recorded 34% identity over the entire length of the putative CinK protein. This correlates with the AbsA1 protein which is thought to be involved in global negative regulation of Streptomyces coelicolor antibiotic synthesis (Brian, P., Riggle, P. J., Santos, R. A. and Champness, W. C. J. Bacteriol. 178 (11), 3221–3231 (1996)). This predicted gene appears to be translationally coupled to the predicted cinR gene.

cinorf10 (FIG. 22) The protein translation product of this predicted gene has no homology to any gene product of known function. This predicted gene may be translationally coupled to the predicted cinorf11 gene.

cinorf11 (FIG. 23) The protein translation product of this predicted gene has no homology to any gene product of known function. This predicted gene may be translationally coupled to the predicted cinorf10 gene.

cinR1 (FIG. 24) The protein translation product of this predicted gene has 38% identity along its entire length to the N-terminal region of the AfsR-g protein from Streptomyces griseus (Umeyama, T., Lee, P. C., Ueda, K. and Horinouchi, S. Microbiology 145 (Pt 9), 2281–2292(1999)) and 38% identity along its entire length to the N-terminal region of the AfsR-g protein from Streptomyces coelicolor A3(2) (Horinouchi, S., Kito, M., Nishiyama, M., Furuya, K., Hong, S. K., Miyake, K. and Beppu, T. Gene 95 (1), 49–56 (1990)).

cinorf12 (FIG. 25) The protein translation product of this predicted gene has no homology to any gene product of known function.

cinorf13 (FIG. 26) The protein translation product of this predicted gene has no homology to any gene product of known function.

cinorf14 (FIG. 27) This is not a complete potential gene with the 3′ end being truncated. The protein translation product of this predicted gene has no homology to any gene product of known function.

EXAMPLE 2 Construction of a Plasmid Tool for the Production of Artificial Variants of Cinnamycin

By the introduction of new restriction sites within and downstream of the cinnamycin structural gene, cinA, it was possible to generate a replaceable cassette which enabled the cinnamycin production process to be harnessed for the production of variants.

The cinA structural gene was encoded on the plasmid pDWFT4 which possesses a 4872 bp BamHI fragment derived from the Streptomyces cinnamoneus cinnamoneus DSM 40005 chromosome. Within the BamHI fragment are two unique restriction sites XhoI (see FIG. 4 cut site 1728C↓TCGAG) and NdeI (see FIG. 4 cut site 2056CA↓TATG). The XhoI site lies within the leader peptide encoding region of cinA and the NdeI site lies downstream of the cinA gene. These two sites form a convenient cassette which is replaced by a similar region that is generated by PCR with oligonucleotides incorporating changes to the native sequence so that new restriction sites are made. These new sites are placed either side of the propeptide region of cinA enabling the native propetide encoding region to be removed and replaced with double stranded oligonucleotides encoding propeptides of choice.

The new restriction sites that have been incorporated are StuI and SpeI. These sites were chosen because there are no StuI or SpeI sites present in the plasmid pDWFT9, described above. This presents an opportunity to construct libraries of variant propeptide regions in this plasmid by replacing the propeptide region with double stranded oligonucleotides that are redundant at specified positions. The restriction site StuI was selected because it can be incorporated without altering the encoded CinA peptide. An A1838G substitution of the pDWFT4 BamHI fragment introduces a StuI site, exchanging the GAA codon for a GAG codon (both of which code for glutamate residues). This site is four codons upstream of the first propeptide codon and enable the whole propeptide region to be exchanged. The SpeI site was to be incorporated by making three changes immediately downstream of the cinA stop codon. These changes were G1908C, G1910A and C1912T of the pDWFT4 BamHI fragment. However, the introduction of these changes also incorporated a spontaneous change in the sequence (see below).

The above plan was executed in the following manner. The 4872 bp BamHI fragment of pDWFT4 was subcloned into a vector that does not possess any XhoI, StuI, SpeI or NdeI sites: The plasmid pBlueScriptIIks does not possess either a StuI or a NdeI site but does have XhoI and SpeI sites. The XhoI and SpeI sites of pBluescriptII KS are unique and positioned in the poly-linker region of the plasmid and can be destroyed by cutting with XhoI and end-filling with Klenow fragment polymerase, followed by ligation and isolation of the modified plasmid to give plasmid pNOX. The process is then repeated on pNOX with SpeI to give pNOXS. The plasmid pNOXS was then cut with BamHI and the 4872 bp BamHI fragment of pDWFT4 cloned into it to yielding pDWFT17.

Oligonucleotide primer pairs were made which introduced sequence changes producing either the StuI or the SpeI sites described above. These primers were:

FTP25=5′-CTT CGT GTG CGA CGG CAA CAC C-3′ homology with the pDWFT4 BamHI fragment starts at position 1880 and stops at position 1901 of FIG. 4

Spe1=5′-GCA GCA ACT AGT TAC TTG GTG TTG CCG TCG-3′ Its homology with the pDWFT4 BamHI fragment starts at position 1889 and stops at position 1918 of FIG. 4

Stu=5′-CCA CGG AGG CCT TCG CCT GCC GCC AGA GCT GC-3′ Its homology with the pDWFT4 BamHI fragment starts at position 1831 and stops at position 1862 of FIG. 4

Stu1=5′-GGC GAA GGC CTC CGT GGC GGC GAT GTC CTT GG-3′ Its homology with the pDWFT4 BamHI fragment starts at position 1847 and stops at position 1806 of FIG. 4

Xho=5′-TTC AGC AGT CCG TCG TGG ACG-3′ Its homology with the pDWFT4 BamHI fragment starts at position 1687 and stops at position 1707 of FIG. 4

Nde=5′-GCG GAT ACG CGT TAC CCA TAC C-3′ Its homology with the pDWFT4 BamHI fragment starts at position 2062 and stops at position 2083 of FIG. 4

The StuI site was introduced first by producing PCR fragments using pDWFT4 as a template. The primer pairs Stu and Nde were used with Pfu-polymerase to produce the fragment StuPCR1 using the following reaction conditions: a 50 μl reaction using 1× Pfu-polymerase buffer (Promega) 100 pg template DNA, 200 μM dNTPs, 20 pmol each primer, 5% DMSO and the following thermal cycle: a denaturation step at 94° C. for 3 min followed by 25 cycles with denaturation at 94° C. for 35 s, annealing at 55° C. for 1 min and elongation at 68° C. for 1 min 30 s. A last elongation step was done at 68° C. for 5 min. Subsequently the primer pairs Stu1 and Xho were used with Taq-polymerase to produce the fragment StuPCR2 using similar conditions to those for StuPCR1 but with 1× Taq-buffer and elongation steps carried out at 72° C. These fragments were then purified by agarose gel electrophoresis into 50 μl water. Then 0.5 μl of each PCR fragment were mixed and used as template for a PCR with Pfu polymerase and primer pairs Xho and Nde to produce fragment StuPCR3 using conditions similar to those for StuPCR1 but with only 10 cycles of the thermal cycle. The plasmid pDWFT17 was cut with XhoI and NdeI and purified away from the small fragment that has been released using agarose gel electrophoresis. The PCR product StuPCR3 was then be cut with XhoI and NdeI and ligated into the XhoI/NdeI cut pDWFT17 to generate a new plasmid, pDWFT19, which possesses an StuI site in the position described above as demonstrated by restriction digests with StuI.

The SpeI site was then introduced by producing PCR fragments using pDWFT19 as template. The primer pairs FTP25 and Nde were used with Pfu-polymerase to produce the PCR fragment SpePCR1 (conditions as for StuPCR1) and then primer pairs Spe1 and Xho were used with Pfu-polymerase to produce the PCR fragment SpePCR2 (conditions as for StuPCR1). These fragments were purified by agarose gel electrophoresis and mixed in approximately equimolar amounts then subject to PCR with Pfu-polymerase and primer pairs Xho and Nde to produce the PCR fragment SpePCR3 (conditions as for StuPCR3). This PCR product was then used to replace the region between the XhoI and NdeI restriction sites of pDWFT17. The plasmid pDWFT17 was cut with XhoI and NdeI and purified away from the small fragment that was released -using agarose gel electrophoresis. The PCR product SpePCR3 was cut with XhoI and NdeI and ligated into the XhoI/NdeI cut pDWFT17 to generate a new plasmid, pDWFT21. This plasmid has been shown to possess both the SpeI and StuI restriction sites described above by sequencing, however, the sequence also shows that a 3 bp insert downstream of the SpeI site has been introduced (see FIG. 29).

It was decided to replace the cinA pro-peptide encoding region of pDWFT21 encompassed by the StuI/SpeI sites with a tetracycline resistance cassette. This cassette was over 1 Kb in size and it would, therefore, be easy to identify the fragment of pDWFT21 left by excision of this cassette using StuI/SpeI restriction endonucleases.

The above was achieved by using PCR, with Taq-polymerase, to produce a copy of the tetracycline resistance gene, Tc, from pBR322 with a StuI site immediately downstream of the stop codon and a SpeI 121 bp upstream of the start codon using the following primers:

tet3=5′-GCG GCG AGG CCT CGC CGG CTT CCA TTC AGG

tet4=5′-GCG GCG ACT AGT AAT AGG CGT ATC ACG AGG

The reaction conditions used to make this PCR fragment were the same as those for StuPCR2. This was then used to replace the StuI/SpeI fragment, encoding the propeptide region of cinA, of pDWFT21 thus generating pDWFT33. This last construct was used to make cinnamycin-derivative constructs.

Large double stranded oligos were made which were variations on the pDWFT21 StuI/SpeI fragment cinA-propeptide encoding region which incorporated changes that resulted in the cinnamycin cluster producing duramycin or duramycinB instead of cinnamycin. These were constructed from 88mer single stranded oligonucleotides (duranA and duranB which encode the propeptide regions for duramycin and duramycinB respectively) that were annealed to a complimentary 20 mer single stranded oligonucleotide (endfill) which was then elongated with pfu-polymerase to produce 88mer double stranded oligonucleotides using conditions similar to those for StuPCR1 but with only one cycle of melting, annealing and elongation. The oligonucleotide sequences were:

duranA =  5′-GCG GCG AGG CCT TCG CCT GCA AGC AGA GCT GCA GCT TCG GCC CGT TCA CCT TCG TGT GCG ACG GCA ACA CCA AGT AAC TAG TCC GGC C-3′ duranB =  5′-GCG GCG AGG CCT TCG CCT GCC GCC AGA GCT GCA GCT TCG GCC CGC TCA CCT TCG TGT GCG ACG GCA ACA CCA AGT AAC TAG TCC GGC C-3′ endfill = 5′-GGC CGG ACT AGT TAC TTG GT-3′

These double stranded oligonucleotides were cleaned by using a Qiagen gel extraction kit by adding 50 μl of sterile distilled water to the 50 μl of reaction mixture then proceeding as though this were a 100 mg gel slice. The double stranded oligonucleotides were eluted from the qiagen column in 40 μl water. They were subsequently digested with StuI and SpeI and used to replace the StuI/SpeI Tc gene fragment of pDWFT33 resulting in two plasmids; pDWFT40 (duranB) and pDWFT42 (duranA). The cinnamycin structural gene cinA was therefore replaced with a duramycin structural gene or a duramycinB structural gene as appropriate and as described above. These plasmids were then used to reconstitute the duramycin equivalents of pDWFT9 in the same manner as pDWFT4. This process resulted in pDWFT52 which carries a duramycinB structural gene and pDWFT54 which carries a duramycin structural gene. These plasmids were then transformed into S. lividans 1326. Transformants were selected and the resulting strains, DW52 and DW54 were bioassayed for cinnamycin and cultures grown for MALDI-TOF analysis as described above.

Results

The strains DW52 and DW54, which are predicted to make duramycinB and duramycin respectively, were tested to determine if they could inhibit the growth of B. subtillis in bioassays.

The strains DW52 and DWS4 inhibit the growth of B. subtillis in bio-assays indicating that they each produce an antibiotic compound. This indicates that the changes to the propeptide encoding region of cinA still allow production of an antibiotic compound by the cinnamycin cluster. See Table 3.

To check that these compounds are duramycinB and duramycin supernatants from liquid cultures were examined using MALDI-TOF mass-spectrometry.

Neither DW52 or DW54 produced a compound with the molecular weight of cinnamycin indicating that the changes in the pro-peptide regions of their respective cinA genes abolished their cinnamycin clusters abilities to produce cinnamycin. However, as predicted from the changes made to their cinA pro-peptide regions, DW52 was able to produce a compound with the expected MW of duramycinB and DW54 was able to produce a compound with the expected MW of duramycin. This indicates that we have successfully engineered the cinnamycin cluster to produce variants of cinnamycin. See Table 4.

EXAMPLE 3 Defining the Roles of Some of the Genes Carried on pDWFT9 in the Cinnamycin Production Cluster

The Creation of a Plasmid that Lacks the Genes Upstream of cinorf7 and cinR1

In order to determine if cinorf3, cinorf4, cinorf12, cinorf13 and cinorf14 are involved in the production of cinnamycin a strain was created that lacks all or parts of these genes. In order to facilitate this it was decided to create a version of pDWFT4 wherein the BamHI end upstream of cinorf7 was moved so that cinorf3 and most of cinorf4 was deleted and a version of pDWFT5 was created so the Asp718 end upstream of cinR1 was moved so that cinorf13, cinorf14 and most of cinorf12 were deleted. These two modified plasmids could then be reassembled in a similar manner to that which gave rise to pDWFT9 (described above).

The first step in this process was to generate the variant of pDWFT4. A PCR product was generated using the following two primers:

BAM=5′-GGC GCC GGA TCC TAC CGC AAC GAC GGC ACC GAG C; and NDE (described above)

The first six nucleotides of primer BAM are random G+C which are there only to make digestion of the subsequent PCR fragment with BamHI easier. The next six nucleotides constitute the new BamHI site which is to be introduced and the remaining nucleotides are homologous to the cinnamycin cluster from position 961 to 982. The PCR product produced using BAM and NDE was 1123 bp long and was produced using pDWFT4 as a template and Taq-polymerase other reaction conditions were the same as those for StuPCR2. It was then digested with BamHI and XhoI to generate an approximately 770 bp fragment with a BamHI compatible end and a XhoI compatible end. This fragment was then purified by agarose gel electrophoresis and cloned into pBluescriptIIKS that had been cut with BamBI and XhoI to give pDWFT11. The BamHI fragment from pDWFT4 was sub-cloned into BamHI cut pUC18 so that the XhoI site within the BamHI fragment was closest to the XbaI site of pUC18 to give pDWFT14f. The plasmid pDWFT11 was then digested with XbaI and XhoI which releases the cloned PCR fragment plus a small piece of the pUC18 polylinker region. This fragment was then purified by agarose gel electrophoresis and cloned into pDWFT14f that had been cut with XbaI and XhoI to give pDWFT15. This restores the native conformation of the cinA gene and creates a new BamHI fragment that corresponds to the region of pDWFT4 that lies between position 961 and 4872 of FIG. 4. This BamHI fragment was subsequently cloned into pDWFT6 and thence into pOJ436 in a similar manner to that in which pDWFT4 gave rise to pDWFT8, to yielding pDWFT25.

The second step in this process was to generate the variant of pDWFT5. A PCR product was generated using the following two primers:

KPN=5′-GGC GCC GGT ACC GAG GAC GTC GAG CTG TTC GAG C (The first six nucleotides of primer KPN are random G+C which are there only to make digestion of the subsequent PCR fragment with Asp718 easier. The following six nucleotides constitute the new Asp718 site which is introduced and the remaining nucleotides are homologous to the cinnamycin cluster from position 15621 to 15599)

FTP1=5′ CAG GTC GCC GAC GAT CTC GTC G

These primers were used to generate a PCR fragment using Pfu-polymerase and pDWFT5 as a template otherwise the reaction conditions were the same as those for StuPCR1. The PCR fragment was approximately 1025 bp long and was digested with BamHI and Asp718 to give a fragment that was approximately 956 bp long which was then purified by agarose gel electrophoresis and cloned into pUC18 cut with BamHI and Asp718 to give pDWFT16. An approximately 6.5 kb BamHI fragment was cloned from S. cinnamoneus cinnamoneus 40005 chromosomal DNA in a manner similar to that used to clone the Asp718 fragment in pDWFT5 with the modification that the chromosomal DNA was cut with BamHI and cloned into BamHI cut pBluescriptII to give pDWFT3. The 6.5 kb BamHI from pDWFT3 corresponding to positions 8016 to 14660 of FIG. 4, was cloned into BamHI cut pDWFT16 such that the portions of cinR1 on the fragment and pDWFT16 are contiguous, yielding pDWFT24. This plasmid was then cut with BglII and EcoRI which releases a approximately 6.9 kb fragment (which corresponds to positions 8730 to 15621 of FIG. 4) that was purified by agarose gel electrophoresis and cloned into pDWFT5 that had been cut with BglII and EcoRI and the approximately 6.3 kb fragment purified by agarose gel electrophoresis to give pDWFT27. This plasmid contains an Asp718 fragment that corresponds to positions 5423 to 15621 of FIG. 4. The final step was to digest pDWFT27 with Asp718 and purify the approximately 10 kb fragment by agarose gel electrophoresis and clone it into Asp718 cut pDWFT25 so that the portion of the cinX gene carried on the Asp718 fragment corresponds to the portion of the cinM gene carried on pDWFT25, yielding pDWFT28. This plasmid was then transformed into S. lividans 1326. The DNA carried on pDWFT28 corresponds to the region between positions 961 to 15621 of FIG. 4). A transformant was selected and the resulting strain, DW28, was bioassayed for cinnamycin and cultures grown for MALDI-TOF analysis as described above.

Construction of Single Gene Deletions from the Cinnamycin Cluster Carried on pDWFT9

A series of constructs was created in which the single genes were removed so that the open-reading frame was completely missing from the start codon to the stop codon and either deleted completely, replaced with a StuI restriction site or replaced with a tetracycline resistance gene, Tc, derived from pDWFT33. This was to formally test the hypothesis that these genes were essential for cinnamycin production.

Construction of a cinorf7 Deletion

This was achieved by replacement of the desired gene with a PCR generated replacement cassette, which carries a selectable marker, using homologous recombination. In this case the replacement cassette used was the Tc gene, which confers tetracycline resistance, from pDWFT33. A plasmid carrying the gene to be replaced is transformed into E.coli BW25113 pIJ790 (available from the JIC) which possesses the plasmid pIJ790 (pIJ790 is based on the plasmid pKD20 (Datsenko and Wanner, 2000) but carries a chloramphenicol resistance gene (cat) instead of an ampicillin resistance gene (bla)) which carries an arabinose inducible recombination system based on that of the λ phage. PCR primers are designed which are homologous to the desired replacement cassette at their 3′-ends and have 5′-extensions which are homologous to the DNA flanking the region to be replaced. A PCR product is prepared using these primers which is then transformed into E.coli BW25113 pIJ790 plus target plasmid. The induced recombinase within the cell then uses the regions of homology, incorporated into the 5′-extensions of the PCR primers, to the sequences flanking the target DNA to replace the target DNA with the replacement cassette. Transformants can then be selected for using the selectable marker carried on the replacement cassette.

The oligonucleotide primers incorporated StuI restriction sites between the regions homologous to the flanking regions of the gene to be replaced and the regions homologous to the Tc replacement cassette. It was subsequently possible to remove the Tc replacement cassette by StuI restriction digestion to leave a StuI site in place of cinorf7.

The following oligonucleotide primers were synthesised:

7A=5′-TCG TTC TCA CCG GGA ACC GAC TGG ATG GGG AAA CGG GCC AGG CCT CGC CGG CTT CCA TTC AGG. This primer has homology to the cinnamycin cluster from position 1228 to 1266; and

7B 5′-ACC TCC GAT GTT GAG GTG AAT CCC GGC ACC CGG CGG GTG AGG CCT AAT AGG CGT ATC ACG AGG. This primer has homology to the cinnamycin cluster from position 1665 to 1627

A PCR was prepared that was labelled PCR7 using 7A and 7B as primers with Taq-polymerase and pDWFT33 as a template using a reaction mixture similar to that for StuPCR2 and the following thermal cycle 3 min at 94° C. followed by 5 cycles of melting at 94° C. for 35 sec, annealing at 55° C. for 1 min and elongation at 52° C. for 2 min then 20 cycles of melting at 94° C. for 35 sec, annealing at 60° C. for 1 min and elongation at 72° for 2 min. The PCR product was then purified by agarose gel electrophoresis. The plasmid pDWFT7 was transformed into E. coli BW25113 pIJ790 (available from the JIC). E. coli BW25113 pIJ790 pDWFT7 was grown in 10 ml SOB (Hanahan, 1983) with chloramphenicol(25 μg/ml) apramycin and L-arabinose (final concentration of 10 mM) at 30° C. to an OD₆₀₀ of ˜0.6 and then made electro-competent by washing twice with 10 ml ice-cold 10% glycerol and resuspended in 100 μl 10% glycerol. Cells were electroporated with ˜100 ng of purified PCR7. Electroporation was carried out in 0.2 cm ice-cold electroporation chambers using a BioRad GenePulser II set to the following parameters: 200 Ω, 25 μF and 2,5 kV. Shocked cells were added to 1 ml LB (Luria-Bertani medium; Sambrook et al., 1998), incubated 1 h at 30° C. and then spread onto LB agar+tetracycline (10 μg/ml) and incubated o/n at 37° C. to select for the successful replacement of the target gene by the PCR product containing the Tc gene. In this way a variant of pDWFT7 was selected in which cinorf7 was replaced with a StuI flanked Tc gene which was labelled pDWFT73. This plasmid was then used to create a variant of pDWFT9 in which cinorf7 was replaced with the StuI flanked Tc gene, in a similar manner to which pDWFT7 was used to create pDWFT9, to give pDWFT77. This plasmid was then digested with StuI and the large fragment produced was purified by agarose gel electrophoresis and religated to create pDWFT78, a version of pDWFT9 in which cinorf7 was replaced with a StuI site. This plasmid was then introduced into S. lividans 1326 by conjugation. This was carried out as follows. The plasmid pDWFT78 was transformed into E. coli ET12567/pUZ8002. A single colony of the resulting strain (ET12567/pUZ8002/pDWFT78 was inoculated into 10 ml LB containing kanamycin (25 μg/ml), chloramphenicol (25 μg/ml) and apramycin (50 μg/ml) and grown overnight at 37° C. The overnight culture was diluted 1:100 in fresh LB with antibiotic selection (see above) and grown at 37° C. to an OD₆₀₀ of approximately 0.4–0.6. The cells were washed twice with an equal volume of LB to remove antibiotics and resuspended in 1 ml of LB.

For each conjugation, approximately 10⁸ Streptomyces spores were added to 500 μl 2×YT broth, heat shocked at 50° C. for 10 min, allowed to cool and then mixed with 500 μl ET12567/pUZ8002/pDWFT78 cells, spun briefly and most of the supernatant was poured off. The pellet was resuspended in the residual liquid and plated out on SFM agar+10 mM MgCl₂ (Kieser et al., 2000) and incubated at 30° C. for 16–20 h.

Plates were overlaid with 1 ml water containing 0.5 mg nalidixic acid (which kills E. coli, thereby selecting for the Streptomyces cells) and 1 mg apramycin and incubated at 30° C. for 3–6 days. Exconjugants were streaked onto SFM+nalidixic acid (50 μg/ml) and apramycin (50 μg/ml) The strain thus created, C78, was bioassayed for cinnamycin production, as previously described, and grown as lawns on SFM+ and apramycin (50 μg/ml) for spore preps to prepare liquid cultures for use in MALDI-TOF assays. These liquid cultures were prepared as described before but instead of subjecting the spent media to organic solvent extractions it was diluted 1/10 in 10% formic acid and used directly in the MALDI-TOF mass-spectrophotometer.

Construction of a cinA Deletion

This was achieved by producing overlapping PCR products where, in each PCR product, one of the primer sequences had homolgy to regions of the DNA that immediately flank the cinA gene. These primers also have a certain amount of overlap between each other so that the subsequent PCR primers can be annealed to each other and extended so that the resulting product can be amplified with the flanking PCR primers.

The following oligonucleotide primers were synthesised:

FTP35=5′-GGC GAC AGC AGC GTC TCG GAC C. This primer has homology to the cinnamycin cluster from position 811 to 832;

LA=5′-GGC AGC AGC CAC GGC TTA CCT CCG ATG TTG AGG. This primer has homology to the cinnamycin cluster from position 1670 to 1650 and from 1919 to 1908;

RA=5′-CGG AGG TAA GCC GTG GCT GCT GCC TCT AGG This primer has homology to the cinnamycin cluster from position 1659 to 1650 and from 1908 to 1925; and

FTP28=5′-TTC AGG TAG AAG CGG TGG TAG G This primer has homology to the cinnamycin cluster from position 2795 to 2774

Using Pfu polymerase and pDWFT4 as a template, PCRs were prepared using the primer pair FTP35 and LA, using similar reaction conditions to StuPCR1, to give a PCR product that was labelled CINAPCR1 whilst, using similar reaction conditions, RA and FTP28 were used to produce a PCR product labelled CINAPCR2. These PCR products were purified by agarose gel electrophoresis then PCR using primer pairs FTP35 and FTP28 to give PCR product CINAPCR3 in a similar manner to that used for the creation of StuPCR3. This product was then purified by agarose gel electrbphoresis and digested with SalI and PstI and cloned into pUC18 that had been cut with SalI and PstI, and purified by agarose gel electrophoresis, to give pDWFT35. The plasmid pDWFT14r (made similarly as pDWFT14f but with the approximately 5 Kb BamHI fragment oriented in the opposite direction) was digested with Asp718 and SalI and the approximately 900 bp fragment purified by agarose gel electrophoresis and cloned into pDWFT35 that had been cut with Asp718 and SalI, and purified by agarose gel electrophoresis, to give pDWFT55. The plasmid pDWFT4 was then cut with PstI and XbaI and the approximately 2.5 kb fragment was purified by agarose gel electrophoresis and cloned into pDWFT55 that had been cut with PstI and XbaI, purified by agarose gel electrophoresis, to give pDWFT56.

The resulting plasmid pDWFT56, is similar to pDWFT4 except that it lacks the cinA gene. This plasmid was then used to reconstruct a cinnamycin cluster similar to pDWFT9, but lacking cinA, via a similar pathway to that used to make pDWFT9 to give pDWFT69. This plasmid was then introduced into S. lividans 1326 by conjugation as described for the construction of a cinorf7 deletion. The resulting strain, C69, was bioassayed for cinnamycin and cultures grown for MALDI-TOF analysis as described for construction of a cinorf7 deletion.

Construction of a cinM Deletion

This was achieved by producing overlapping PCR products where, in each PCR product, one of the primer sequences had homolgy to regions of the DNA that immediately flank the cinM gene. These primers also have a certain amount of overlap between each other so that the subsequent PCR primers can be annealed to each other and extended so that the resulting product can be amplified with the flanking PCR primers.

The following oligonucleotide primers were synthesised:

XHO (see above);

LM=5′-TGG AGC CAC TCC ATG-CGA ATT TCT CCT GCG GTC G. This primer has homology to the cinnamycin cluster from position 5337 to 5326 and from 2058 to 2037;

RM=5′-AGA AAT TCG CAT GGA GTG GCT CCA CCA TGG. This primer has homology to the cinnamycin cluster from position 2047 to 2058 and from 5326 to 5343; and

FTPMR=5′-CGG CCG AGC TCG ACG ATC TCC. This primer has homology to the cinnamycin cluster from position 5449 to 5429.

Using Pfu polymerase and pDWFT9 as a template PCRs were prepared using the primer pair XHO and LM, using similar reaction conditions to StuPCR1, to give a PCR product that was labelled CINMPCR1. Using similar reaction conditions, RM and FTPMR were used to produce a PCR product labelled CINAPCR2. These PCR products were purified by agarose gel electrophoresis then subject to PCR using primer pairs XHO and FTPMR to give PCR product CINAPCR3 in a similar manner to that used for the creation of StuPCR3. This product was then purified by agarose gel electrophoresis and digested with XhoI and Asp718 and cloned into the approximately 4.7 kb fragment from pDWFT7 that had been cut with XhoI and Asp718 and purified by agarose gel electrophoresis, to give pDWFT43. The plasmid pDWFT43 is similar to pDWFT7 except that it lacks the cinM gene. This plasmid was then used to reconstruct a cinnamycin cluster similar to pDWFT9, but lacking cinM, via a similar pathway to that used to make pDWFT9 to give pDWFT68. This plasmid was then introduced into S. lividans 1326 by conjugation as described for construction of a cinorf7 deletion. The resulting strain, C68, was bioassayed for cinnamycin and cultures-grown for MALDI-TOF analysis as described for construction of a cinorf7 deletion.

Construction of a cinX Deletion

The construction of a cinX deletion was achieved in a similar manner to that used for cinorf7 to leave a StuI site in place of cinX.

The following primers were used:

XA=5′-CCC GCC GTC GCA CCA CGA ACA GTA AGG AGT GGC TCC ACC AGG CCT CGC CGG CTT CCA TTC AGG. This primer has homology to the cinnamycin cluster from position 5301 to 5339; and

XB=5′-TCC TTG GTG CCG CGC GGT GCG CGG ACG ACG GGT GCC GGG AGG CCT AAT AGG CGT ATC ACG AGG. This primer has homology to the cinnamycin cluster from position 6356 to 6318.

Using XA and XB as primers a PCR was prepared in a similar manner to that for cinorf7 that was labelled PCRX. The plasmid pDWFT5 was digested with Asp718 and the approximately 11.5 kb fragment was purified by agarose gel electrophoresis and cloned into pDWFT7 that had been cut with Asp718, and purified by agarose gel electrophoresis, such that the native orientation of the cinnamycin cluster was restored to give pDWFT74. The plasmid pDWFT74 was transformed into E. coli BW25113 pIJ790. The BW25113 pIJ790 pDWFT74 strain was then used to produce electro-competent cells which were transformed by electroporation with PCRX in the same manner as described for cinorf7. In this way a variant of pDWFT74 was selected in which cinX was replaced with a StuI flanked Tc gene which was labelled pDWFT79. This plasmid was then used to create a variant of pDWFT9 in which cinX was replaced with the StuI flanked Tc gene by digesting it with XbaI and Asp718 and cloning it into XbaI and Asp718 cut pOJ436 to give pDWFT82. This plasmid was then digested with StuI and the large fragment produced was purified by agarose gel electrophoresis and religated to create pDWFT90, a version of pDWFT9 in which cinX was replaced with a StuI site. This plasmid was then introduced into S. lividans 1326 by conjugation as described for construction of a cinorf7 deletion. The resulting strain, C90, was bioassayed for cinnamycin and cultures grown for MALDI-TOF analysis as described for construction of a cinorf7 deletion.

Construction of a cinR Deletion

This was achieved in a similar manner to that used for cinorf7 to leave a StuI site in place of cinR.

The following primers were used:

RA=5′-TCA GCA CTG TCG AAG AAC ACC TCG CGC CGG GAG CGG CAT AGG CCT CGC CGG CTT CCA TTC AGG. This primer has homology to the cinnamycin cluster from position 11798 to 11760; and

RB=5′-CTG CTG ACA CCC GGC CCG TAG CGG TCA CGG CTC ACA CCG AGG CCT AAT AGG CGT ATC ACG AGG. This primer has homology to the cinnamycin cluster from position 11072 to 11110.

Using RA and RB as primers a PCR was prepared in a similar manner to that prepared for cinorf7 that was labelled PCRR. The plasmid pDWFT5 was transformed into E. coli BW25113 pIJ790. The strain BW25113 pIJ790 pDWFT5 was then used to produce electro-competent cells which were transformed by electroporation with PCRR in the manner described for cinorf7. In this way a variant of pDWFT5 was selected in which cinR was replaced with a StuI flanked Tc gene which was labelled pDWFT80. This plasmid was then used to create a variant of pDWFT9 in which cinR was replaced with the StuI flanked Tc gene, in a similar manner to which pDWFT5 was used to create pDWFT9, to give pDWFT85. This plasmid was then digested with StuI and the large fragment produced was purified by agarose gel electrophoresis and re-ligated to create pDWFT88, a version of pDWFT9 in which cinR was replaced with a StuI site. This plasmid was then introduced into S. lividans 1326 by conjugation as described for construction of a cinorf7 deletion. The resulting strain, C88, was bioassayed for cinnamycin and cultures grown for MALDI-TOF analysis as described for construction of a cinorf7 deletion.

Construction of a cinR1 Deletion

This was achieved in a similar manner to that used to replace cinorf7 to replace cinR1 with the Tc replacement cassette.

The following primers were used:

SARPA=5′-GTC TTC AGG GTG CGG CTC GAT GAG CGA AGG GGA GAG TTC AGG CCT CGC CGG CTT CCA TTC AGG. This primer has homology to the cinnamycin cluster from position 15199 to 15161; and

SARPB=5′-CTC GTG CAC CGC CGG CGC GCG CGC CGG GCG GTG GGC GGC AGG CCT AAT AGG CGT ATC ACG AGG. This primer has homology to the cinnamycin cluster from position 14336 to 14374.

Using SARPA and SARPB as primers a PCR was prepared in a similar manner to that prepared for cinorf7 that was labelled PCRSARP. The plasmid pDWFT5 was transformed into E. coli BW25113 pIJ790. The strain BW25113 pIJ790 pDWFTS was then used to produce electro-competent cells which were transformed by electroporation with PCRSARP in the manner described for cinorf7. In this way a variant of pDWFT5 was selected in which cinR1 was replaced with a StuI flanked Tc gene which was labelled pDWFT81. This plasmid was then used to create a variant of pDWFT9 in which cinR1 was replaced with the StuI flanked Tc gene, in a similar manner to which pDWFT5 was used to create pDWFT9, to give pDWFT89. This plasmid was then introduced into S. lividans 1326 by conjugation as described for construction of a cinorf7 deletion. The resulting strain, C89, was bioassayed for cinnamycin and cultures grown for MALDI-TOF analysis as described for construction of a cinorf7 deletion.

Results

All of the deletion constructs of the cinnamycin cluster described above were examined by bio-assay to determine whether they could still produce an antibiotic compound. See Table 5.

Strains DW28 (deletions of the regions upstream of cinA and cinR1) and C90 (cinX deletion) still produce an antibiotic compound whilst strains C78 (cinorf7 deletion), C69 (cinA deletion), C68 (cinM deletion), C88 (cinR deletion) and C89 (cinR1 deletion) do not. These results indicate that the regions deleted from the cinnamycin clusters in C78, C69, C68, C88 and C89 (which correspond to the genes cinorf7, cinA, cinM cinR and cinR1 respectively) are essential for the inhibition of growth of B. subtillis in a bio-assay. However, the regions deleted from the cinnamycin cluster in DW28 (which include all of cinorf3, cinorf13 and cinorf14 and most of cinorf4 and cinorf12) and C90 (cinX deletion) are not essential for the inhibition of growth of B. subtillis in a bio-assay. Supernatants from these strains were examined by MALDI-TOF mass spectrometry to determine if a compound with the MW of cinnaycin was still made by these strains. See Table 6.

The MALDI-TOF mass spectrometry data shown in Table 6 indicate that DW28 and C78 still produce cinnamycin (MW=2039) whilst C69, C68 and C90 do not. This indicates that cinA, cinM and cinX are essential for cinnamycin production. However, in the three strains shown in Table 6 that do produce cinnamycin there is also a peak with a MW of 2023 daltons (16 daltons lighter than cinnamycin). This peak is absent from two of the three strains unable to make cinnamycin, C69 (cinA deletion) and C68 (cinM deletion), but is present in C90 (cinX deletion).

Discussion

All of the results discussed below pertain to the functions of the genes of the cinnamycin cluster in S. lividans 1326.

We have demonstrated that by the introduction of unique restriction sites either side of the cinA pro-peptide encoding region we can replace the region of cinA that encodes the structural gene for cinnamycin with one that encodes a variation on cinnamycin. In this case we have evidence that shows that the cinnamycin cluster can be manipulated to produce duramycin and duramycinB instead of cinnamycin. The approach exemplified herein can be used for the production of many different and novel variations of cinnamycin.

With the strain DW28 we have also shown that positions 1 to 961 and 15621 to 17083 of the cinnamycin cluster as represented in FIG. 4 are not essential for the production of cinnamycin in S. lividans 1326. This means that cinorf3, cinorf13 and cinorf14 are not essential to the production of cinnamycin. It also suggests that cinorf4 is not essential as it is only present in a truncated form that also lacks its promoter region. It also suggests that the product of cinorf12 may not be essential for cinnamycin production.

The strains C69 and C68 show that the genes cinA and cinM are both essential for cinnamycin production by both bio-assay and mass spectrometry analysis. The gene cinA is the structural gene for cinnamycin which we have already demonstrated can be manipulated to make the cinnamycin cluster produce natural variants of cinnamycin. The gene cinM is thought to encode a LanM type protein that would be responsible for the production of the lanthionine residues of cinnamycin.

The strain C78 does not produce a zone of inhibition in a bio-assay but according to mass spectometry analysis does produce cinnamycin. This suggests that although it produces enough cinnamycin to be detected in a MALDI-TOF mass spectrometer it does not produce enough to inhibit the growth of B. subtilis. This indicates that although cinorf7 is not essential for cinnamycin production it does greatly enhance its production.

The strain C90 produces a zone of inhibition in a bio-assay but does not produce a compound with the molecular weight of cinnamycin. However it, along with the other cinnamycin producing strains in Table 6, does produce a compound 16 daltons lighter than cinnamycin. Amongst the post-translational modifications of the cinnamycin propeptide is the addition of an oxygen atom to the aspatate residue to form beta-hydroxy aspartate. The results shown here suggest that the process that adds this oxygen atom is not efficient and some of the cinnamycin pre-cursor, which we shall term deoxycinnamycin, is secreted before it is modified and this is represented by the peak with a MW of 2023 as detected by MALDI-TOF mass spectrometry. That C90 only produces a peak with a MW that corresponds to deoxycinnamycin suggests the product of cinX is an enzyme responsible for the addition of the oxygen atom to the aspartate residue of the propeptide to form cinnamycin. This would mean that by removing cinX from the cinnamycin cluster and combining this with the methods described above for the production of variants of cinnamycin one could produce both variants and deoxy-variants. Also by increasing the copy number of cinX in a strain one may be able to increase the amount of cinX product within a cell and thus reduce the amount of deoxycinnamycin (or deoxy-variant) produced by a S. lividans strain hosting the cinnamycin cluster.

The bio-assay results for strains C88 and C89 suggests that the genes cinR and cinR1 are at least necessary for the production of enough cinnamycin to be detected by bio-assay in a S. lividans strain.

TABLE 1 The effect on the growth of B. subtilis by strains of S. lividans possessing either the plasmid pDWFT9 or the vector pOJ436. Inhibition of the Growth of Strain B. subtilis S. + cinnamoneus cinnamoneus DSM 40005 DW9a-1 + DW9a-2 + DW9a-3 + DW9a-4 + DW9a-5 + Dw9a-6 + DW9a-7 + DW9a-8 + DW9a-9 + DW436-1 − DW436-2 − DW436-3 − DW436-4 −

TABLE 2 The detection of compounds with similar molecular weights to cinnamycin by MALDI-TOF mass spectrometry Strain Streptomyces cinnamoneus cinnamoneus DSM 4000 5DW9a-1 DW436-4 Growth media TSB YEME TSB YEME TSB YEME Presence + + + + − − of molecule of MW 2039.9 ± 0.1

TABLE 3 The effect on the growth of B. subtilis by strains of S. lividans possessing plasmids that carry a cluster encoding variants of cinnamycin Strain DW436-4 DW9a-1 DW52 DW54 Inhibition of the − + + + Growth of B. subtilis

TABLE 4 The detection of cinnamycin and its derivatives by MALDI-TOF mass spectrometry Presence of molecule with Strain MW of DW436-4 DW9a-1 DW52 DW54 cinnamycin MW = 2039.9 ± − + − − 0.1 durainycinB MW = 2005 − − + − duramycin MW = 2011 − − − +

TABLE 5 The effect on the growth of B. subtilis by strains of S. lividans possessing variants of pDWFT9 in which different sections of DNA been deleted. Strain DW436-4 DW9a-1 DW28 C78 C69 C68 C90 C88 C89 Inhibition of − + + − − − + − − the growth of B. subtilis

TABLE 6 The detection of cinnamycin by MALDI-TOF mass spectrometry by strains of S. lividans possessing variants of pDWFT9 in which different sections of DNA have been deleted. Strain C9 DW28 C78 C69 C68 C90 MW = 2039 + + + − − − MW = 2023 + + + − − + Note: Strain C9 possesses pDWFT9 and so is similar to strain DW9a-1 but was created using conjugation instead of transformation. 

1. A recombinant expression cassette comprising a cinA (SEQ ID NO: 10) orf, a cinM (SEQ ID NO: 11) orf and optionally a cinX (SEQ ID NO: 12) orf.
 2. A set of recombinant expression cassettes comprising a cinA (SEQ ID NO: 10) orf, a cinM (SEQ ID NO: 11) orf and optionally a cinX (SEQ ID NO: 12) orf.
 3. A recombinant expression cassette comprising a cinA (SEQ ID NO: 10) open reading frame (orf), a cinM orf (SEQ ID NO: 11), a cinT (SEQ ID NO: 13) orf, a cinH (SEQ ID NO: 14) orf, a cinY (SEQ ID NO: 15) orf and optionally a cinX (SEQ ID NO: 12) orf.
 4. A set of recombinant expression cassettes together comprising a cinA (SEQ ID NO: 10) orf, a cinM (SEQ ID NO: 11) orf, a cinT (SEQ ID NO: 13) orf, a cinH (SEQ ID NO: 14) orf, a cinY(SEQ ID NO: 15) orf and optionally a cinX (SEQ ID NO: 12) orf.
 5. The expression cassette of claim 3 or the set of expression cassettes of claim 4, further comprising a streptomyces antibiotic regulatory proteins (SARP) binding site, a cinorf7 (SEQ ID NO: 9) orf, a cinR (SEQ ID NO: 19) orf, a cinK (SEQ ID NO: 20) orf and a cinR (SEQ ID NO: 23) orf.
 6. The cassette or set according to claim 5, wherein the SARP binding site is upstream of the cinorf7 (SEQ ID NO: 9) orf.
 7. The cassette or set according to claim 6, wherein the cinorf7 (SEQ ID NO: 9) orf forms an operon with the cinA (SEQ ID NO: 10), cinM (SEQ ID NO: 11), cinX (SEQ ID NO: 12), cinT (SEQ ID NO: 13), cinH (SEQ ID NO: 14) and cinY(SEQ ID NO: 15) orfs.
 8. The cassette or set according to any one of claims 3 or 4, further comprising one or more orfs selected from the group consisting of cinorf3 (SEQ ID NO: 6), cinorf4 (SEQ ID NO: 7), smallorf (SEQ ID NO: 8), cinZ (SEQ ID NO: 16), cinorf8 (SEQ ID NO: 17), cinorf9 (SEQ ID NO: 18), cinorf10 (SEQ ID NO: 21), cinorf11 (SEQ ID NO: 22), cinorf12 (SEQ ID NO: 24), cinorf13 (SEQ ID NO: 25) and cinorf14 (SEQ ID NO: 26).
 9. The cassette or set according to claim 8, wherein said one or more orfs include one of more orfs selected from the group consisting of cinorf4 (SEQ ID NO: 7), smallorf (SEQ ID NO: 8), cinZ (SEQ ID NO: 16), cinorf8 (SEQ ID NO: 17), cinorf9 (SEQ ID NO: 18), cinorf10 (SEQ ID NO: 21), cinorf11 (SEQ ID NO: 22) and cinorf12 (SEQ ID NO: 24).
 10. The cassette or set according to claim 9, wherein said one or more orfs include one or more orfs selected from the group consisting of smallorf (SEQ ID NO: 8), cinZ (SEQ ID NO: 16), cinorf8 (SEQ ID NO: 17), cinorf9 (SEQ ID NO: 18), cinorf10 (SEQ ID NO: 21) and cinorf 11 (SEQ ID NO: 22).
 11. The cassette or set according to claim 10, wherein said one or more orfs include cinZ (SEQ ID NO: 16) and/or cinorf8 (SEQ ID NO: 17).
 12. The expression cassette of claim 3 further comprising regulatory sequences suitable for directing transcription and translation of the orfs in a host cell.
 13. A vector, or set of vectors, comprising, or together comprising, a cassette or set of cassettes according to claim 1 or
 2. 14. An isolated expression system comprising a vector or set of vectors according to claim
 13. 15. The isolated expression system according to claim 14, wherein the expression system is a cell.
 16. The isolated expression system according to claim 15, wherein the cell is a bacterium.
 17. The isolated expression system according to claim 16, wherein the bacterium is an actinomycete.
 18. The isolated expression system according to claim 17, wherein the actinomycete bacterium is a streptomycete.
 19. The isolated expression system according to claim 18, wherein the streptomycete bacterium is S. lividans.
 20. An isolated set of recombinant expression cassettes together comprising a cinA orf, a cinM (SEQ ID NO: 11) orf, a cinT (SEQ ID NO: 13) orf, a cinH (SEQ ID NO: 14) orf and a cinY (SEQ ID NO: 15) orf and optionally a cinX (SEQ ID NO: 12) orf wherein the cinA orf encodes the polypeptide sequence of FIG. 11, optionally with one or more amino acids of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with the amino acid found in the corresponding position in the propeptide sequence of duramycin A, B or C or ancovenin.
 21. The set according to claim 4, further comprising regulatory sequences suitable for directing transcription and translation of the orfs in a host cell.
 22. A recombinant expression cassette comprising a cinA orf, a cinM (SEQ ID NO: 11) orf and optionally a cinX (SEQ ID NO: 12) orf, wherein the cinA orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with up to six amino acids of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin.
 23. A recombinant expression cassette comprising a cinA orf, a cinM (SEQ ID NO: 11) orf and optionally a cinX (SEQ ID NO: 12) orf, wherein the cinA orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with one or more of the amino acids in positions 2, 3, 7, 10, 12 and 13 of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin.
 24. The cassette of claim 22 or claim 23 further comprising a cinT (SEQ ID NO: 13) orf, a cinH (SEQ ID NO: 14) orf, and a cinY (SEQ ID NO: 15) orf.
 25. The cassette of claim 22 or claim 23 wherein the B-type lantibiotic other than cinnamycin is selected from the group consisting of duramycin A, B and C and ancovenin.
 26. An isolated set of recombinant expression cassettes together comprising a cinA orf, a cinM (SEQ ID NO: 11) orf and optionally a cinX (SEQ ID NO: 12) orf, wherein the cinA orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with up to six amino acids of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin.
 27. An isolated set of recombinant expression cassettes together comprising a cinA orf, a cinM (SEQ ID NO: 11) orf and optionally a cinX (SEQ ID NO: 12) orf, wherein the cinA orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with one or more of the amino acids in positions 2, 3, 7, 10, 12 and 13 of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin.
 28. The set of claim 26 or claim 27 further comprising a cinT (SEQ ID NO: 13) orf, a cinH (SEQ ID NO: 14) orf and a cinY (SEQ ID NO: 15) orf.
 29. The set of claim 26 or claim 27 wherein the B-type lantibiotic other than cinnamycin is selected from the group consisting of duramycin A, B and C and ancovenin.
 30. A vector, or set of vectors, comprising, or together comprising, a cassette or set of cassettes according to claim 26 or
 27. 31. An isolated expression system comprising a vector or set of vectors according to claim
 30. 32. The isolated expression system according to claim 31, which is a cell.
 33. The isolated expression system according to claim 32, wherein the cell is a bacterium.
 34. The isolated expression system according to claim 33, wherein the bacterium is an actinomycete.
 35. The isolated expression system according to claim 34, wherein the actinomycete bacterium is a streptomycete.
 36. The isolated expression system according to claim 35, wherein the streptomycete bacterium is S. lividans.
 37. A recombinant expression cassette comprising a cinA open reading frame (orf), wherein said orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with up to six amino acids of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin, said cassette further encoding a cinM orf, a cinT orf, a cinH orf and a cinY orf and optionally a cinX orf, wherein said orfs each have a nucleic acid sequence which encodes a polypeptide that is identical to the sequences as set out in SEQ ID NO's: 11–15 respectively, and wherein said orfs, when introduced into SEQ ID NO: 4 in place of nucleic acid encoding SEQ ID NO's: 11–15 respectively are capable of providing for production of a molecule having a lantibiotic activity in a host cell.
 38. A set of recombinant expression cassettes together comprising: a cinA open reading frame (orf), wherein said orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with up to six amino acids of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin, a cinM orf, a cinT orf, a cinH orf and a cinY orf and optionally a cinX orf, wherein said orfs each have a nucleic acid sequence which encodes a polypeptide that is identical to the sequences as set out in SEQ ID NO's: 11–15 respectively, and wherein said orfs, when introduced into SEQ ID NO: 4 in place of nucleic acid encoding SEQ ID NO's: 11–15 respectively are capable of providing for production of a molecule having a lantibiotic activity in a host cell.
 39. A recombinant expression cassette comprising a cinA open reading frame (orf), wherein said orf encodes the polypeptide sequence of SEQ ID NO: 10, optionally with up to six amino acids of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin, said cassette further encoding cinorf7, wherein said cinorf7 has a nucleic acid sequence which encodes a polypeptide that is identical to the sequence as set out in SEQ ID NO: 9, and wherein said orfs, when introduced into SEQ ID NO: 4 in place of nucleic acid encoding SEQ ID NO: 9 is capable of providing for production of a molecule having a lantibiotic activity in a host cell.
 40. The recombinant expression cassette of claim 39 wherein said cinA open reading frame encodes the polypeptide sequence of SEQ ID NO: 10, optionally with one or more of the amino acids in positions 2, 3, 7, 10, 12 and 13 of the propeptide sequence of cinA (amino acids 60 to 78 of SEQ ID NO: 10) replaced with an amino acid found in the corresponding position in the propeptide sequence of a B-type lantibiotic other than cinnamycin.
 41. The recombinant expression cassette of claim 39 wherein said cinorf7 has a nucleic acid sequence which encodes the polypeptide of SEQ ID NO:
 9. 42. A vector, or set of vectors, comprising, or together comprising, a cassette or set of cassettes according to claim 39, 40 or
 31. 43. An isolated expression system comprising a vector or set of vectors according to claim
 42. 44. The isolated expression system according to claim 43, which is a cell.
 45. The isolated expression system according to claim 44, wherein the cell is a bacterium.
 46. The isolated expression system according to claim 45, wherein the bacterium is an actinomycete.
 47. The isolated expression system according to claim 46, wherein the actinomycete bacterium is a streptomycete.
 48. The isolated expression system according to claim 47, wherein the streptomycete bacterium is S. lividans. 